Top Ansys RaptorH Alternatives

Ansys MotorCAD serves as a specialized tool tailored for the design of electric machines. It enables rapid simulations of multiphysics throughout the complete torque-speed operating spectrum. With MotorCAD, engineers can assess various motor topologies within this full range, leading to designs that are fine-tuned for size, efficiency, and overall performance. The software comprises four modules—Emag, Therm Lab, and Mech—facilitating swift and iterative multiphysics calculations, thereby allowing users to transition from initial concepts to final designs more expeditiously. Moreover, MotorCAD empowers users to investigate a wider array of motor topologies and thoroughly analyze the effects of advanced losses during the preliminary phases of electromechanical design, aided by its efficient data input system. The latest update introduces robust new features aimed at optimizing design, enhancing multi-physics analysis, and improving system modeling for electric motors. Additionally, the speed of multiphysics simulations across the entire torque-speed spectrum ensures that engineers can make informed decisions quickly. In summary, MotorCAD significantly accelerates the design process while providing comprehensive analytical capabilities.

OrCAD® X represents a comprehensive platform for PCB design that enhances user experience, boosts performance, and streamlines automation. This software suite encompasses various applications such as schematic design, PCB layout, simulation, and data management. Among its offerings, OrCAD X Capture stands out as a widely used tool for creating and documenting electrical circuits. Complementing this is PSpice®, an integrated virtual SPICE simulation engine within Capture, which empowers users to prototype and validate their designs through top-tier native analog, mixed signal, and advanced analysis capabilities. Additionally, OrCAD X Presto and OrCAD X PCB editor facilitate seamless collaboration between ECAD and MCAD teams, enabling designers to produce superior PCBs more efficiently. OrCAD X Presto features a user-friendly interface tailored for novice designers as well as electrical engineers and PCB designers who prioritize rapid PCB development, making it an essential tool in today's fast-paced design environment. The combined functionalities of these applications ensure that designers can meet the evolving demands of the industry effectively.

Ansys Exalto is a specialized software tool for post-LVS RLCk extraction that aids integrated circuit (IC) designers in accurately detecting unknown crosstalk across different design hierarchy blocks by extracting lumped-element parasitics and establishing a precise model for electrical, magnetic, and substrate interactions. This tool is designed to work seamlessly with most LVS tools and can significantly improve the RC extraction capabilities of your chosen software. By leveraging Ansys Exalto’s post-LVS RLCk extraction features, IC designers can proficiently predict electromagnetic and substrate coupling effects, allowing for the signoff of circuits that were once considered "too large to analyze." The models produced by the software can be back-annotated to the schematic or netlist, ensuring compatibility with all circuit simulators. As the demand for RF and high-speed circuits grows in modern silicon systems, accurately modeling electromagnetic coupling has become increasingly vital, as it plays a crucial role in the success of silicon designs. Therefore, Ansys Exalto proves to be an indispensable tool for designers striving to tackle the intricate challenges of contemporary circuit design with utmost accuracy and efficiency. Furthermore, its capabilities not only streamline the design process but also enhance the reliability of the final product, making it a valuable resource for any IC design team.

BQRG's software suite offers patented tools for automated electronic design analysis and optimization to enhance your design processes: SynthelyzerTM ECAD Plugin supercharges PCB design by providing real-time stress analysis, derating, and thermal simulations, all while seamlessly integrating with ECAD systems to ensure optimal component choices and avert costly mistakes. fiXtress® stands out as a powerful asset in reliability engineering; featuring cutting-edge FMECA, stress, and failure predictions, it helps to prolong product life and reduce downtime significantly. When paired with Synthelyzer™, this combination leads to unmatched design optimization. CircuitHawk™ helps speed up time-to-market by identifying design issues at an early stage, and its sophisticated verification and stress analysis capabilities lay a solid groundwork for creating dependable products. apmOptimizer® is designed to enhance asset value and operational efficiency; through LCC analysis and predictive maintenance strategies, it helps lower costs, optimize spare parts inventory, and guarantees seamless operations. Finally, CARE® prioritizes product safety and ensures adherence to regulatory standards, providing a complete solution for compliance and quality assurance in your designs. This suite collectively transforms the electronic design landscape, making it more efficient and reliable.

Ansys VeloceRF streamlines the design workflow by drastically reducing the time needed to synthesize and model complex spiral devices and transmission lines. Users can generate geometries for inductors or transformers in seconds, with modeling and analysis completed in just a few minutes. The software is designed to integrate effortlessly with leading EDA platforms, enabling the creation of layouts that are ready for tape-out. With Ansys VeloceRF, engineers can design devices featuring tightly packed components and lines, leading to a more efficient silicon layout. By evaluating the coupling between different inductive devices before delving into detailed layouts, it helps reduce the design footprint and may even do away with the necessity for guard rings. The size of inductors and the crosstalk among them can greatly influence the overall die size, and Ansys VeloceRF facilitates the development of smaller components through the application of optimization criteria and geometry constraints. Additionally, it examines the coupling between multiple inductors to optimize silicon space and boost the performance of inductors within the circuit, ensuring a more effective and efficient design process. This advanced feature not only increases the accuracy of designs but also simplifies the workflow for engineers managing intricate circuit layouts, ultimately leading to faster project completions and improved outcomes.

Ansys RedHawk-SC is recognized as the gold standard for voltage drop and electromigration multiphysics verification in digital design endeavors. Its cutting-edge analytics quickly identify weaknesses and allow for exploratory scenarios that improve power efficiency alongside overall performance. Featuring a cloud-based architecture, RedHawk-SC can perform full-chip evaluations with exceptional speed and capacity. The tool's signoff precision is backed by prominent foundries for each finFET node, reaching down to 3nm technology. By utilizing advanced power analytics, Ansys RedHawk-SC enables the development of robust, low-power digital designs without sacrificing performance, providing designers with comprehensive methodologies to detect and address dynamic voltage drops. Additionally, the dependability of RedHawk-SC's multiphysics signoff analysis significantly reduces the risks associated with projects and technologies, rendering it an indispensable resource for engineers. Moreover, the accuracy of RedHawk's algorithms has been confirmed by leading foundries across all finFET processes, showcasing their success in numerous tapeouts. This all-encompassing strategy not only reinforces RedHawk-SC's standing as a vital tool in the face of contemporary digital design challenges but also ensures that engineers can deliver optimal results efficiently.

The CADISON E&I Designer is built upon extensive engineering expertise and the sophisticated technical capabilities of Electrical Engineers and Developers, all grounded in Object Oriented Technology. Designed to improve efficiency in electrical engineering, the tool effectively tackles challenges throughout the project lifecycle, including change management, centralized documentation, real-time updates, and the seamless integration of information and data with visual components. Scalability and customization are two fundamental features of CADISON E&I Designer that allow it to align effortlessly with your business model and systems. Our ultimate objective is to guarantee accuracy, speed, and timely project delivery for our users. What distinguishes the CADISON Team from its competitors is its unique offerings tailored to meet user requirements. By placing a strong emphasis on the needs of users, the CADISON E&I Designer revolutionizes the management and execution of engineering projects, fostering a more efficient workflow. This innovative approach not only streamlines processes but also enhances collaboration among project stakeholders, ultimately leading to more successful project outcomes.

Design Force represents a groundbreaking advancement in the realm of electrical design, enabling users to transcend the limitations typically associated with traditional electrical design processes. As the complexity of product design continues to escalate, incorporating technologies that often elude the capabilities of conventional ECAD tools, Design Force equips design teams with the ability to tap into system-level design insights right from the initial planning and conceptual stages. This early access facilitates the simultaneous layout of each product board, all while maintaining a comprehensive view of the entire system. Utilizing the latest in industry-standard hardware and software, Design Force allows users to operate within a native 3D environment, thereby optimizing performance through the use of cutting-edge 64-bit, multithreading, and multicore processors. In addition to its robust design capabilities, Design Force is designed to be compatible with various client-server models, providing flexibility for users to work seamlessly from their corporate cloud if desired. Furthermore, this innovative tool enhances collaboration among team members, ensuring a more integrated approach to product development.

You can effectively navigate the schematic and layout in PCBWeb Designer using either your mouse or keyboard. Zooming in and out of the active design area can be easily done with the scroll wheel or by pressing the page-up and page-down keys. To quickly return to a zoom level that displays your entire design, simply click the icon in the lower right corner or press the home key. For panning across the interface, hold down the right mouse button while moving the mouse, or alternatively, utilize the scroll bars found at the bottom and side of the application. Furthermore, PCBWeb Designer includes a robust component catalog, which enables you to search, filter, and place components that have both a symbol and footprint, thereby increasing your design efficiency. This integrated feature not only simplifies the design workflow but also ensures that users can locate necessary components quickly, enhancing productivity. Overall, PCBWeb Designer is designed to facilitate a smoother design experience for all users.

Ansys HFSS is a highly adaptable 3D electromagnetic simulation software, tailored for the design and analysis of high-frequency electronic devices like antennas, components, interconnects, connectors, integrated circuits (ICs), and printed circuit boards (PCBs). This tool equips engineers with the capability to accurately model and simulate a diverse array of high-frequency electronic products, including antenna arrays, RF and microwave components, high-speed interconnects, filters, and IC packages. Employed worldwide, Ansys HFSS is vital for the development of high-speed electronics, which are essential for communication systems, advanced driver assistance systems (ADAS), satellite technologies, and internet-of-things (IoT) applications. Renowned for its unmatched capabilities and superior accuracy, HFSS empowers engineers to address RF, microwave, IC, PCB, and EMI challenges within even the most complex systems. The HFSS simulation suite boasts an extensive selection of solvers that address a wide range of electromagnetic problems, providing comprehensive support for engineers engaged in cutting-edge electronic design. Notably, Ansys HFSS not only enhances innovation but also significantly improves efficiency in the realm of high-frequency electronics, making it an indispensable tool for engineers in the industry. By streamlining the design process, it ultimately contributes to the advancement of technology in various high-tech fields.

The schematic editor enables users to create an unlimited number of designs without encountering any paywalls for additional features. With an integrated schematic editor and a comprehensive library of schematic symbols, you can quickly embark on your design projects. You can craft professional-grade PCB layouts featuring as many as 32 copper layers. KiCad now boasts a push-and-pull router capable of routing differential pairs while interactively adjusting trace lengths. Additionally, KiCad offers a 3D viewer that allows you to examine your design on an interactive canvas, giving you the ability to rotate and pan to observe details that may be challenging to discern in a 2D view. There are multiple rendering options available, allowing you to modify the board's appearance or selectively hide and reveal certain elements. The schematic capture process in KiCad is both rapid and effective, equipped with all necessary tools to facilitate this task. The user interface emphasizes productivity, making it easy to work efficiently. Furthermore, large designs can be organized into hierarchical subsheets, ensuring that complexity knows no bounds. This flexibility allows for the creation of intricate designs tailored to various needs.

Cadence® introduces its Sigrity X OptimizationPI™ technology, which conducts a comprehensive AC frequency analysis of circuit boards and IC packages, enabling performance enhancement and potential savings of 15% to 50% on decoupling capacitor expenditures. This technology caters to both pre-layout and post-layout investigations, efficiently identifying the most economical decoupling capacitor options. The foundation of Sigrity X OptimizePI lies in the established Cadence hybrid magnetic circuit analysis methodology, fused with the innovative Sigrity Optimization engine, allowing users to swiftly determine optimal placement and decap site selection. By leveraging this advanced tool, engineers can enhance design efficiency while simultaneously reducing costs.

Electromagnetic (EM) simulation offers crucial insights before moving on to the physical prototyping phase. To boost both the speed and accuracy of your EM simulations, they should be customized effectively. By integrating EM analysis with circuit simulations, you can significantly enhance overall efficiency. Although completing EM simulations may take several hours, linking your EM simulation tools with PathWave Circuit Design software can drastically cut down on import and export times. This integration is designed to optimize your workflow, allowing for a seamless combination of EM analysis and circuit simulations. The 3D EM solid modeling environment supports the creation of custom 3D objects and facilitates the import of models from various CAD systems, which is vital for preparing a 3D geometry for 3DEM simulation. This preparation includes the definition of ports, boundary conditions, and material properties. Moreover, the environment comes equipped with a Finite Difference Time Domain (FDTD) simulator, which plays a crucial role in compliance testing for Specific Absorption Rate (SAR) and Hearing Aid Compatibility (HAC), ensuring that the designs align with necessary regulatory requirements. By leveraging these sophisticated features, you can not only streamline your design process but also significantly improve the efficacy of your electromagnetic analysis while ensuring that your products are compliant with industry standards. This careful orchestration of tools and processes ultimately leads to more innovative and reliable designs.

Enhance your methodology for RF simulation by emphasizing the thorough design, scrutiny, and validation of radio frequency integrated circuits (RFICs). Ensure confidence in your projects by leveraging steady-state and nonlinear solvers during both the design and verification stages. Utilizing wireless standard libraries significantly accelerates the process of validating complex RFICs. It is vital to verify IC specifications through RF simulation before finalizing an RFIC, as these simulations account for various elements, including layout parasitics, complex modulated signals, and digital control circuitry. With PathWave RFIC Design, you can conduct simulations across both frequency and time domains, allowing for effortless transitions between your designs and Cadence Virtuoso. Achieve precise modeling of components on silicon chips, and refine your designs by employing optimization techniques such as sweeps and load-pull analysis. The integration of RF designs into the Cadence Virtuoso ecosystem is made more efficient, while the application of Monte Carlo and yield analysis can significantly enhance overall performance. Furthermore, debugging is simplified through safe operating area alerts, enabling the quick adoption of state-of-the-art foundry technologies to maintain a competitive edge in innovation. This comprehensive strategy for RFIC design not only boosts efficiency but also significantly enhances the overall quality and dependability of the resultant products, making it a crucial element in modern electronic design. By adopting this approach, engineers can achieve greater precision and reliability in their RFIC projects, ultimately leading to more successful outcomes in various applications.

HyperLynx provides a comprehensive set of tools for signal integrity, power integrity, 3D electromagnetic modeling, and electrical rule checking specifically designed for high-speed digital applications. By combining intuitive features with automated workflows, HyperLynx makes it easier for mainstream system designers to conduct high-speed design analyses, allowing for the early detection and correction of potential issues throughout the design process. Its seamless compatibility with various PCB tools enhances its value within any PCB design environment. The HyperLynx suite guarantees a thorough analysis framework, integrating best-practice design rule checking with detailed simulations focused on both signal and power integrity. Utilizing cutting-edge 3D electromagnetic solvers, it generates accurate interconnect models that significantly improve the design workflow. Users can evaluate design trade-offs prior to layout and thoroughly validate their designs before manufacturing through extensive post-layout analyses. This versatile tool serves multiple applications, such as SerDes channels, DDRx memory interfaces, and general signal integrity evaluations. Furthermore, it streamlines the design and validation of power-delivery networks (PDN), ensuring compliance with impedance requirements in an accessible format. With its powerful capabilities, HyperLynx equips engineers to confidently develop high-performance designs while minimizing risks associated with potential design flaws. By fostering a more efficient design process, it ultimately enhances the overall quality and reliability of high-speed digital systems.

The Cadence AWR Design Environment Platform simplifies the creation of RF and microwave products by leveraging design automation to enhance engineering productivity and reduce turnaround times. This all-in-one platform provides engineers with advanced tools for high-frequency circuit and system simulations, along with in-design electromagnetic (EM) and thermal analyses, resulting in efficient and precise high-frequency intellectual property. Its intuitive and robust user interface facilitates smart, customizable design workflows that cater to the specific needs of contemporary high-frequency semiconductor and PCB technologies. Moreover, it features a cohesive design capture system that enables a fluid front-to-back physical design process, ensuring that any changes made in the electrical schematic are automatically reflected in the corresponding physical layout. This synchronization not only streamlines the design process but also significantly promotes collaboration among engineering teams, creating a more agile and responsive development environment. Ultimately, the platform empowers engineers to innovate rapidly while maintaining high standards of accuracy and efficiency.

The PCB Layout software is a sophisticated engineering application used for designing printed circuit boards, featuring intelligent manual routing suitable for high-speed and differential signals, a shape-based autorouter, comprehensive verification mechanisms, and broad import/export options. Design specifications are defined through net classes and class-to-class regulations, alongside accurate settings configured for different object types within each class or layer. DipTrace significantly improves the design process by implementing real-time design rule checks (DRC), which alert users to errors immediately, preventing them from being saved. It also provides a 3D visualization of the board, which can be exported to mechanical CAD systems for additional modeling. The rigorous design rule checks, connectivity validations of nets, and comparisons with the source schematic ensure the resulting product meets the highest quality standards. Operating within a cohesive environment, DipTrace facilitates smooth transitions from circuit schematics to board layouts, allowing for updates from the schematic and back annotation capabilities. Nets are systematically organized into classes with customizable settings, complemented by class-to-class regulations that enhance orderliness. Vias are meticulously arranged according to their types, such as through and blind/buried vias, contributing to an organized and effective design process. The extensive features of DipTrace not only streamline PCB design tasks but also empower engineers to uphold exceptional quality standards throughout the entire workflow, making it an indispensable asset in the field of electronic design. Furthermore, the ability to quickly adapt to changes and implement revisions in real-time further solidifies DipTrace's reputation as a leading tool for PCB designers.

Ansys PathFinder-SC is a powerful and high-capacity tool specifically created for the effective planning, validation, and approval of IP and full-chip SoC designs, ensuring their durability and dependability against electrostatic discharge (ESD). By identifying the key elements that lead to design issues potentially resulting in chip failures due to occurrences like charged-device models (CDM) and human body models (HBM), Ansys PathFinder-SC provides essential insights for improvements. Its cloud-native architecture leverages the capabilities of thousands of computing cores, allowing for rapid full-chip turnaround times. Additionally, this solution has achieved certification from prominent foundries for performing current density evaluations and ESD approvals. With an all-encompassing integrated data modeling, extraction, and transient simulation engine, PathFinder-SC presents a streamlined end-to-end process for ESD verification. The tool utilizes a single-pass model that efficiently interprets standard design formats, sets ESD criteria, extracts resistive-capacitive (RC) values for the power network, and conducts ESD simulations to explore root causes, ultimately offering actionable recommendations for corrections and optimizations—all within a unified application. This comprehensive level of integration not only boosts operational efficiency but also significantly enhances the reliability of chip designs, making it an indispensable resource for engineers in the field. Moreover, the continuous updates and support ensure that users remain equipped with the latest advancements in ESD verification technology.

PathWave ADS optimizes the design workflow by offering integrated templates that enable users to kickstart their projects with greater efficiency. With an extensive array of component libraries, finding the necessary parts becomes a simple task. The automatic synchronization with layout provides a clear view of the physical arrangement as schematic designs are created. This data-driven methodology allows teams to verify that their designs meet the required specifications. PathWave ADS boosts design confidence through its visualization and analytics tools, which produce informative graphs, charts, and diagrams to assist users. Additionally, wizards, design guides, and templates facilitate a quicker design process. The all-encompassing design workflow includes schematic design, layout, and simulations encompassing circuit, electro-thermal, and electromagnetic aspects. As frequencies and speeds in printed circuit boards (PCBs) continue to escalate, maintaining signal and power integrity becomes increasingly vital. Challenges related to transmission line effects can result in failures of electronic devices. It is crucial to accurately model traces, vias, and interconnects for a realistic simulation of the board, thereby ensuring that potential issues are identified and addressed early on. This comprehensive approach not only enhances efficiency but also significantly strengthens the overall reliability of electronic designs, ultimately contributing to the successful deployment of high-performance devices.

Ansys Path FX provides exhaustive timing assessments for an entire System on Chip (SoC) while maintaining high standards without any trade-offs. Its unique cell modeling achieves SPICE-level precision for timing across different voltage and variation scenarios by utilizing a single library. With a fully threaded and distributed architecture, Path FX can efficiently scale to harness the power of thousands of CPUs. The technology behind its path-based timing analysis adeptly takes into account all significant factors affecting delay and constraints across various process, voltage, and temperature conditions. Furthermore, it automatically identifies and simulates every clock path in your design, simplifying the overall analysis workflow. In the current chip design environment, two major challenges include minimizing power consumption with lower supply voltages and managing the growing complexity tied to advanced silicon processes at 7nm and beyond. By effectively tackling these issues, Path FX establishes itself as an indispensable tool for engineers aiming to achieve optimal chip performance and reliability in their designs. This makes it an essential asset in the evolving landscape of semiconductor engineering.

SafeGrid Earthing Software is an exceptional tool for designing effective earthing systems. It utilizes precise, finite element analysis to conduct calculations, ensuring accuracy at every step. Renowned for its affordability, dependability, and user-friendly interface, SafeGrid Earthing Software effectively computes substation grid resistance, touch and step voltages, as well as lightning protection measures. For over a decade, this software has been a valuable asset across various industries. It encompasses all necessary modules to create a secure earthing system, which includes: - Fault current distribution - Soil modeling - Grid analysis - Safety criteria assessment - Secure result generation Additionally, users benefit from the guidance of our team of earthing engineers, providing expert support alongside the software. SafeGrid Earthing Software not only enhances efficiency but also significantly reduces project costs and time. By streamlining the design process, it empowers engineers to focus on other critical aspects of their work.

Cadence®'s Sigrity X PowerSI® technology addresses the escalating challenges associated with switching noise, signal interference, and maintaining target voltage levels. It offers rapid, precise, and comprehensive electrical analyses for complete IC packages and PCBs. This technology can be employed to formulate power and signal integrity guidelines either prior to layout or after, facilitating performance verification and design enhancement without the need for a prototype. Sigrity X's advanced electromagnetic (EM) solver capabilities enable a variety of analyses, such as pinpointing coupling issues with traces and vias, assessing power and ground fluctuations due to simultaneous output switching, and designing areas that meet or exceed voltage specifications. Furthermore, PowerSI technology helps in extracting frequency-dependent parameter models for network configurations while providing visualization of intricate spatial relationships, ensuring that designers can optimize their circuits effectively. This powerful toolset ultimately streamlines the design process and enhances overall product reliability.

JTAG Maps™, a user-friendly extension for Altium, enables engineers to efficiently evaluate the testing capabilities offered by JTAG devices integrated into their designs. Previously, engineers dedicated significant time to manually marking boundary-scan nets within a design to assess their coverage. The boundary scan device model files, known as BSDLs, play an essential role in the JTAG and boundary scanning process by specifying which pins can be manipulated through JTAG. JTAG Maps supports BSDL models and includes an option to 'assume scanner covered.' While many users may opt for the Altium coverage report provided by JTAG Maps, there is also an option to import a more comprehensive analysis. Additionally, data can be exported to JTAG ProVision for in-depth evaluation, allowing engineers to gain further insights. Subsequently, a straightforward message file that encompasses complete fault-coverage details can be re-imported into JTAG Maps for visualization and highlighting purposes. This streamlined process significantly reduces the time engineers need to spend on testing assessments.

Ansys PowerArtist is recognized as the premier RTL design-for-power solution favored by leading low-power semiconductor companies, aiding in the early detection and mitigation of power issues. This innovative platform boasts features such as physically-aware RTL power precision, tools for interactive debugging of power-related challenges, and methodologies driven by analysis aimed at reducing power consumption, alongside unique metrics to assess both power efficiency and vector coverage. Furthermore, it supports swift power profiling grounded in real-world workloads and guarantees a seamless transition from RTL to maintaining the integrity of the physical power grid. The specially crafted physically-aware modeling capabilities of PowerArtist empower semiconductor firms to achieve trustworthy and rapid RTL power accuracy, which aids in making informed decisions at the earliest phases of design. Relying solely on synthesis to evaluate power consumption can prove to be too late; therefore, design teams utilize PowerArtist to meticulously break down and scrutinize power usage, effectively identify inefficient RTL code, and detect any unnecessary toggles present in the design. Additionally, the platform allows for the rapid profiling of extensive cycles, ensuring optimal performance throughout the development process. This all-encompassing methodology not only boosts overall efficiency but also significantly simplifies the design workflow, leading to faster project completion and enhanced product quality.

SOLIDWORKS® Electrical Schematics provides a range of intuitive, standalone tools tailored for electrical design, facilitating the precise definition of connections within complex systems. Its user-friendly interface streamlines challenging tasks like contact cross-referencing and terminal drawings, thus accelerating the product development process while minimizing the repetitive work usually associated with drafting electrical schematics. The Standard version is designed for individual users and focuses on speeding up the design of embedded electrical systems across various equipment and product types. It includes an extensive library of symbols and manufacturer part details that aid in the reuse of standard components, boosting overall design efficiency. In contrast, the Professional version of SOLIDWORKS Electrical Schematic encompasses a collection of collaborative tools aimed at enhancing the integration of electrical systems, enabling teams to collaborate more effectively. Ultimately, these tools are vital for optimizing productivity in electrical design endeavors, ensuring that both individual and team-based projects can achieve their goals more swiftly and efficiently. The combination of these features underscores the importance of SOLIDWORKS Electrical Schematics in modern electrical engineering workflows.

Microwave Office serves as a comprehensive platform for designing a wide array of RF passive components such as filters, couplers, and attenuators, in addition to active devices that operate under small-signal (AC) conditions, including low noise and buffer amplifiers. Its linear architecture facilitates the simulation of S-parameters (Y/Z/H/ABCD), small-signal gain, linear stability, noise figure, return loss, and voltage standing wave ratio (VSWR), and it is enhanced with functionalities like real-time tuning, optimization, and yield analysis. Each E-series portfolio of Microwave Office includes synchronized schematic and layout editors, 2D and 3D visualizers, and a vast collection of libraries containing high-frequency distributed transmission models as well as RF models for surface-mount vendor components that come with footprints. Furthermore, it supports measurement-based simulations and RF plotting features. The Microwave Office PCB variant further augments the design experience by allowing for both linear and nonlinear RF circuit design through the sophisticated APLAC HB simulator, which boasts powerful multi-rate HB, transient-assisted HB, and time-variant simulation engines for thorough RF/microwave circuit analysis. This comprehensive suite of tools empowers engineers to innovate in RF design while effectively optimizing their development processes, ultimately fostering greater efficiency and creativity in their projects. As a result, Microwave Office not only streamlines workflows but also enhances the overall quality of the designs produced.

Ansys Cloud Direct offers a robust and user-friendly HPC cloud solution that will transform your perspective on simulation. In contrast to other cloud-based simulation platforms, Ansys Cloud Direct is effortless to install and use, seamlessly integrates into your existing workflow, and eliminates the need for specialized cloud expertise. The focus of Ansys Cloud Direct is centered around enhancing Workflow, optimizing Performance, and providing exceptional Support. With its intuitive design, users can accelerate their simulation processes without the usual complexities associated with cloud solutions.

FloWare is a suite of valuable enhancements designed to boost efficiency in CAD Flow and PCB design using OrCAD or Allegro. These enhancements were developed to address specific customer requirements related to Setup, Display and Edit, Drafting, Shapes, Check/Review, and Documentation. Installing the FloWare modules is straightforward, requiring no specialized technical knowledge, as the installation wizard simplifies the process. The toolbar displays the menu structure that is compatible with the PCB Editor, making navigation intuitive. Users can select from a variety of available modules to enhance their PCB design productivity significantly. Upon purchase, a license is delivered via email and is valid for your company's location, ensuring easy access to the tools. Each module comes with comprehensive documentation to assist users in maximizing their benefits. Additionally, the user-friendly nature of FloWare allows designers to focus more on creativity and less on technical hurdles.

The CELUS Engineering Platform harnesses the power of artificial intelligence to generate schematics, PCB layouts, and bills of materials with a mere click. By eliminating the manual aspects of the engineering process, we can reduce development times by up to 90%. So, what's stopping you? Now is the perfect time to innovate and set a new benchmark in the industry. Take the plunge—unleash your creativity! There are endless opportunities waiting to be discovered. Question the traditional methods and expand the limits of advancement, since true innovation comes from reimagining the status quo. Become a leader in establishing new standards in your domain and rise as the visionary the world urgently requires. The realm of electronics engineering has never been more accessible and intelligent. Keep ahead of industry trends and redefine the electronic engineering environment. With the CELUS Engineering Platform, we cater to your specific challenges and understand your needs. Our extensive industry expertise allows us to tackle even the most intricate issues you encounter. Don't just survive; excel in this transformative age of engineering! Embrace the change and witness the future unfold before you.

BQR's fiXtress offers a robust solution for assessing the reliability of electronic products. Through derating analysis, it can pinpoint components that may be either excessively stressed or unnecessarily robust, indicating a need for modification. Additionally, the stress-based MTBF predictions deliver a practical timeframe for when product failures might occur following the derating process. FiXtress serves as an advanced Design for Reliability suite that can seamlessly integrate with any Electronic Design Automation tool. The modules within FiXtress can function independently or be combined with others to form a holistic DfR solution. Furthermore, its unique thermal analysis capability provides estimates of the average temperature increase on the cold plate, ensuring accurate stress derating for improved product longevity. This comprehensive approach enhances the overall reliability and performance of electronic designs.