Alternatives to PrimeSim HSPICE

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.

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.

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.

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.

The award-winning mPower solution offers comprehensive power integrity analysis for digital, analog, and 3D integrated circuits across various design flows and scales. By seamlessly integrating analog, semi-custom, and digital power integrity analysis into current design workflows, it efficiently adapts to circuits and chips of any dimension. The mPower tool suite is designed for quick, scalable, and effective analysis, ranging from small blocks to expansive full-chip layouts, ensuring that power-related design objectives and performance standards are met with confidence for all technology types and design variations. Additionally, the mPower analog power integrity analysis solution features simulation-driven, high-capacity dynamic EM/IR analysis to ensure impeccable power integrity verification for analog designs across all design flows and scales. Furthermore, it utilizes industry-standard inputs and optimized memory specifications to enhance scalability while reducing the runtime of digital power integrity assessments, making it an invaluable resource for engineers. This tool not only streamlines the design process but also elevates the reliability of power analysis in complex projects.

Multisim™ software combines industry-standard SPICE simulation with an interactive schematic environment that allows for the immediate visualization and analysis of electronic circuit behavior. Its user-friendly interface is designed to assist educators in reinforcing circuit theory and enhancing students' retention of concepts throughout their engineering studies. By integrating robust circuit simulation and analysis into the design workflow, Multisim™ enables researchers and designers to minimize the number of printed circuit board (PCB) prototypes needed, thus reducing development costs significantly. Specifically tailored for educational purposes, Multisim™ serves as a teaching application for analog, digital, and power electronics courses and labs. With its comprehensive suite of SPICE simulation, analysis, and PCB design tools, Multisim™ empowers engineers to efficiently iterate on their designs and enhance the performance of their prototypes while fostering a deeper understanding of electronic principles. This software not only streamlines the design process but also cultivates a hands-on learning experience for students in the field of electronics.

An animated circuit can convey more information than a thousand equations and charts combined. By superimposing animations of voltages, currents, and charges directly onto the schematic, users gain profound insights into how the circuit functions. The circuit simulation engine, designed specifically for optimal speed and interactive use, allows for seamless one-click simulations, catering to a wide range of components—from basic resistors and logic gates to intricate transistor-level oscillators and mixed-signal systems. During the simulation, users can manipulate switches, adjust potentiometers, modify LED current limiting resistors, and gradually increase input voltages, with the circuit instantly reflecting these alterations in real time. Distinctive mini-waveforms appear over schematic wires, differentiating between digital and analog signals, where constant analog voltages are displayed numerically and digital wires are color-coded for clarity. Additionally, any two time-domain signals can be illustrated in XY mode, enhancing the analytical capabilities. The oscilloscope's scale and grid ticks automatically adjust to optimal values as the data fluctuates, ensuring precise measurements throughout the simulation process. This dynamic feedback loop creates an engaging and educational experience for users looking to deepen their understanding of circuit behavior.

TopSpice is an advanced mixed-mode circuit simulator that operates seamlessly on PCs, combining analog, digital, and behavioral simulation capabilities. It stands out in its price category by providing a sophisticated SPICE simulator, a user-friendly integrated design environment that spans from schematic capture to graphical waveform analysis, and full 64-bit support for enhanced speed and expanded memory usage. Users have the flexibility to create designs through schematic diagrams, text-based netlist (SPICE) files, or a combination of both methods. All simulation and design functionalities are accessible through either the schematic or netlist editor interfaces, facilitating a versatile workflow. Additionally, TopSpice features a powerful mixed-mode mixed-signal circuit simulator that can handle any arbitrary mix of analog components, digital elements, and high-level behavioral blocks. With this software, users can efficiently validate and fine-tune their designs, ensuring optimal performance from the overall system down to individual transistors. Its comprehensive capabilities make it a valuable tool for engineers and designers seeking precision in their simulations.

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.

Synopsys OptSim stands out as a highly acclaimed simulator for photonic integrated circuits (PICs) and fiber-optic systems, empowering engineers to effectively design and refine photonic circuits and associated systems. With its cutting-edge algorithms for both time and frequency domains, it provides a dedicated photonic environment that ensures precise simulation results. OptSim can operate independently, complete with its own graphical user interface, or be integrated within the OptoCompiler Photonic IC design platform for enhanced functionality. When combined with OptoCompiler, it allows for electro-optic co-simulation alongside Synopsys PrimeSim HSPICE and PrimeSim SPICE electrical circuit simulators, offering a seamless experience with the PrimeWave Design Environment that facilitates advanced simulations, analyses, and visualizations, including parametric scans and Monte Carlo methods. Additionally, the software is equipped with a comprehensive array of libraries containing photonic and electronic components, as well as various analysis tools, and is compatible with a wide range of foundry process design kits (PDKs), making it an invaluable resource for engineers in the field. Its versatility and depth of features make Synopsys OptSim a crucial tool for anyone involved in photonic design.

The Synopsys PrimeWave Design Environment serves as a robust and adaptable platform powered by AI for setting up simulations and analyzing various designs, including analog, RF, mixed-signal, custom-digital, and memory designs found within the Synopsys Custom Design Family. It provides an integrated simulation experience that interacts smoothly with all Synopsys PrimeSim simulation engines, enhancing productivity and user-friendliness while offering thorough analytical tools. Functioning as a vital element of the Synopsys AI-Driven Analog Design solution, this environment efficiently optimizes intricate analog designs by navigating through multiple test-benches and numerous process-voltage-temperature (PVT) corners, allowing engineers to swiftly identify design points that align with their requirements. Furthermore, the PrimeWave Design Environment includes a cohesive, workflow-oriented analysis for all PrimeSim Reliability Analysis tools, featuring user-friendly setup, clear visualizations, and capabilities for debugging and identifying root causes, ultimately fostering a design approach that emphasizes reliability. This multifaceted design environment not only improves the efficiency of engineering processes but also empowers users to make informed decisions throughout the design lifecycle.

Electromagnetic (EM) simulation provides valuable insights prior to the physical prototyping stage. Tailor your EM simulations to enhance both speed and precision. Seamlessly integrate EM analysis with your circuit simulations to boost overall efficiency. While EM simulations can often require several hours to complete, you can significantly reduce both import and export times by linking your EM simulation software with PathWave Circuit Design software. This integration allows you to maximize your workflow by combining EM analysis with circuit simulations effectively. The 3D EM solid modeling environment enables the creation of custom 3D objects and supports the import of existing models from various CAD platforms. This is essential for preparing a 3D geometry for 3DEM simulation, which involves defining ports, boundary conditions, and material properties. Additionally, the environment includes a Finite Difference Time Domain (FDTD) simulator, which is vital for compliance testing regarding Specific Absorption Rate (SAR) and Hearing Aid Compatibility (HAC), ensuring that your designs meet necessary regulatory standards. By utilizing these advanced features, you can streamline your design process and enhance the effectiveness of your electromagnetic analysis.

TINACloud is an online version of the well-known TINA software, available in multiple languages and accessible directly through your browser from anywhere in the world without needing any installation. Subscribing to TINACloud is significantly more affordable compared to the traditional TINA software, and those who acquire a license for the downloadable TINA program will benefit from a special bundle that includes TINACloud with all new private licenses of the downloadable version. This page focuses specifically on TINACloud, while more details about the offline TINA software, which can be installed on your personal computer, can be found elsewhere. As a robust online circuit simulator, TINACloud enables users to analyze and design a variety of circuits, including analog, digital, VHDL, Verilog, Verilog A, AMS, MCU, and mixed electronic circuits, as well as special applications in SMPS, RF, communication, and optoelectronics. Additionally, it provides the capability to test microcontroller applications within a mixed circuit environment, making it an invaluable tool for engineers and designers alike.

This platform offers the opportunity to create and evaluate electronic circuits while exploring various hypothetical scenarios without the concern of defective components or poor connections. CircuitLogix accommodates analog, digital, and mixed-signal circuits, and its reliable SPICE simulation provides accurate results that reflect real-world performance. Furthermore, both variants of CircuitLogix come with 3DLab, a "virtual reality" lab environment that aims to closely mimic the look and functionality of genuine devices and instruments. Within 3DLab, users can access around 30 different tools and instruments, such as batteries, switches, meters, lamps, resistors, inductors, capacitors, fuses, oscilloscopes, logic analyzers, and frequency counters. This comprehensive array of resources allows for an immersive and engaging learning experience in electronic circuit design.

Explore the world of electronics through practical examples offered in the PROTO application, where a plethora of components like resistors, diodes, and transistors await your experimentation. Utilize the channel oscilloscope to observe and assess signals effortlessly, while monitoring voltages, currents, and various other parameters during simulations. Experience real-time circuit tuning with the multichannel oscilloscope, enhancing your projects with devices such as Raspberry Pi, Arduino, or ESP32. Additionally, PROTO serves as an effective tool for simulating logic circuits, enabling detailed digital electronic analysis and fostering a deeper understanding of electronic principles. This hands-on approach ensures that you not only learn but also apply your knowledge effectively.

The Easy-wire mode simplifies the process of connecting components, reducing the number of clicks needed and minimizing user frustration. With unit-aware expression evaluation, you can easily visualize various signals of interest, including differential signals and power losses. The in-browser simulation and plotting tools enable quicker design and analysis, ensuring your circuit operates correctly even before you start soldering. Advanced simulation features offer options like frequency-domain (small signal) simulations, the ability to vary circuit parameters across a specified range, and integration of arbitrary Laplace transfer function blocks, among other capabilities. Handling multiple signals is made seamless with customizable plotting windows, along with vertical and horizontal markers for precise measurements and calculations. Additionally, you can easily create generic rectangular symbols for integrated circuits or system-level wiring diagrams with just a few effortless clicks, enhancing your overall design experience. This user-friendly approach allows engineers and designers to focus on creativity rather than get bogged down by complex processes.

Ansys Totem-SC stands out as the established and reliable leader in the realm of power noise and reliability validation for both analog and mixed-signal designs, utilizing a cloud-native elastic compute framework. Recognized as the benchmark solution for voltage drop and electromigration multiphysics sign-off at the transistor level, Ansys Totem-SC has proven its effectiveness across numerous tapeouts, leveraging a cloud-based infrastructure to provide the necessary speed and capacity for comprehensive full-chip assessments. Its accuracy in signoff has been validated by all major foundries, supporting advanced finFET technologies down to 3nm. This platform excels in power noise and reliability analysis specifically for analog mixed-signal intellectual property and fully custom designs. Moreover, it generates IP models that facilitate SOC-level power integrity signoff in conjunction with RedHawk-SC and develops compact chip models for power delivery networks applicable at both chip and system levels. The solution is not only industry-proven but also certified by foundries, making it a highly regarded choice for analog and mixed-signal electromigration and IR analysis. With Ansys Totem-SC, designers can confidently ensure the integrity and reliability of their power delivery systems throughout the design process.

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

Our online circuit simulator effectively connects theoretical concepts with practical application through an easy-to-use interface. This platform enables users to create, simulate, and share electronic circuits in a digital environment, allowing them to observe the interaction of components in real time. By directly manipulating circuit behavior, learning becomes more dynamic and impactful. Educators benefit from DCACLab as it enriches their teaching methods with interactive diagrams and live demonstrations, while students gain a secure environment for experimentation and insight, fostering a profound grasp of electronics. With DCACLab, challenges transform into opportunities for hands-on learning and greater understanding. Experience the capabilities of a realistic multimeter within our interactive simulator, equipped to measure ohms, voltage, and resistance, thus providing a comprehensive and authentic educational experience. Explore the fascinating realm of electronics effortlessly and with clarity, making the journey as enjoyable as it is informative.

The graphical schematic capture interface provides the ability to analyze schematics and generate simulation results, which can then be further examined using the integrated waveform viewer. A crucial aspect of circuit design is the speed at which one can comprehend the circuit, verifying its accuracy and identifying its constraints. LTspice excels compared to numerous other simulation tools, allowing for rapid iterations of your designs. Additionally, keyboard shortcuts offer an efficient alternative to accessing commands in LTspice that would typically require navigating through the menu or toolbar. Our comprehensive library of technical resources covers a diverse array of LTspice subjects, including guidance on using transformers, incorporating third-party models, and creating and managing symbols. Furthermore, these resources aim to enhance your overall understanding and proficiency with the software.

In today's fast-paced business environment, companies encounter intricate design obstacles while managing limited budgets. eCADSTAR transcends being just a PCB layout tool, as it integrates simulation, 3D MCAD capabilities, and wire harness support, all harnessed through cutting-edge technology that offers enterprise-level performance at a budget-friendly price point. Its user-friendly interface makes eCADSTAR an attractive choice for designers of all levels. By utilizing eCADSTAR’s robust design features, teams can streamline and expedite the overall design workflow. The software includes a digitally connected library and intuitive schematic capture, allowing PCB layout engineers to focus more on innovation and less on tool manipulation. Among the various stages of the design process, developing a test plan can be particularly labor-intensive. Without proper upfront simulation, the validation phase can lead to significant time and financial expenditures, but eCADSTAR addresses this challenge with its advanced capabilities in Spice simulation and SI/PI analysis, resulting in reduced test cycle times and increased efficiency overall. Ultimately, eCADSTAR stands out as a powerful ally for engineers striving to navigate the complexities of modern design.

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.

The Synopsys 3DIC Compiler, which is founded on the premier digital implementation platform in the industry and leverages a unified fusion data model, facilitates a smooth transition to 2.5/3D heterogeneous integration. This comprehensive platform supports analysis-driven feasibility studies, multi-die partitioning, and the selection of foundry technology for both prototyping and floor planning in a single environment. As a result, it promotes effective design implementation that encompasses advanced packaging and die-to-die routing, coupled with golden signoff verification. Additionally, the 3DIC Compiler collaborates with Synopsys 3DSO.ai, the first autonomous AI optimization solution in the market for multi-die designs, enhancing system performance and ensuring quality outcomes regarding thermal integrity, signal integrity, and power network design. Widely embraced by clients, the 3DIC Compiler platform has also received certification from prominent foundries, validating its capabilities in advanced process and packaging technologies. This combination of features positions the 3DIC Compiler as a vital tool for engineers aiming to innovate in the realm of integrated circuit design.

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

Synopsys OptoCompiler stands out as the first comprehensive design platform in the industry that seamlessly integrates electronic and photonic design capabilities. This innovative solution merges advanced photonic technology with Synopsys' proven electronic design tools, allowing engineers to efficiently and accurately create and validate intricate designs for photonic integrated circuits. By offering a schematic-driven layout alongside sophisticated photonic layout synthesis within a single interface, OptoCompiler effectively connects photonic specialists with integrated circuit designers, thereby enhancing the accessibility, speed, and flexibility of photonic design processes. The platform's support for electronic-photonic co-design ensures scalable methodologies, while its robust features for hierarchical design facilitate collaboration among multiple designers, significantly reducing product development timelines. Additionally, OptoCompiler is equipped with specialized native photonic simulators that work in tandem with widely recognized electrical simulators, delivering precise simulation results that account for variations in statistical data. This combination of features makes OptoCompiler a pivotal tool for advancing the field of integrated photonic design.

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.

Pharos integrates Ansys' exceptional electromagnetic (EM) engine capabilities with a unique high-capacity circuit simulation engine, enabling comprehensive coupling analysis and the identification of potential EM crosstalk aggressors for each victim node. By pinpointing the most vulnerable nets, designers can strategically direct their design choices to mitigate EM crosstalk issues, thereby reducing risks throughout the design process. This tool not only has an extraordinary extraction engine but also features a built-in simulation component that facilitates in-depth EM analysis and categorizes potential crosstalk aggressors affecting each victim net. As a result, designers can concentrate on the nets that pose the highest risk within their designs. Given the increasing complexity of designs and the extensive range of magnetic field interference, it becomes a daunting challenge to identify every susceptible victim/aggressor net pair affected by EM crosstalk. Therefore, the effective use of Pharos can significantly enhance the reliability and efficiency of the design workflow.

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

Ansys 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.

The framework is built on a thorough depiction of the qubit state while steering clear of directly illustrating gates and various quantum processes through matrices. To facilitate communication among the distributed resources involved in storing and processing quantum states, Intel-QS employs the MPI (message-passing-interface) protocol. Designed as a shared library, Intel-QS integrates seamlessly with application programs, enabling users to leverage its high-performance capabilities for circuit simulations. This library can be compiled on a wide range of systems, encompassing everything from personal laptops to high-performance computing server infrastructures. Additionally, this flexibility ensures that developers can tailor their solutions to meet the specific demands of their quantum computing projects.

For more than 25 years, PSIM has established itself as a premier software for simulating and designing power electronics and motor drives. Boasting an easy-to-navigate interface alongside a powerful simulation engine, PSIM serves as a comprehensive solution tailored to fulfill the simulation and design requirements of its users. It efficiently performs rapid calculations for power converter losses and motor drive efficiencies, while also conducting EMI analysis and managing both analog and digital control systems. Furthermore, PSIM streamlines the process of rapid control prototyping through its automatic embedded code generation feature. With its diverse range of Design Suites, users can swiftly and conveniently develop power supplies, EMI filters, and motor drive systems, making PSIM a versatile tool for engineers in the field. The software's ability to adapt to various design needs further solidifies its reputation as an essential asset in the power electronics industry.

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

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

Numerous circuit simulators exist in the marketplace today. Their advertisements boast about high performance, remarkable speed, being industry-standard (such as SPICE), and being user-friendly with a highly intuitive interface. To determine the effectiveness of a tool, it’s best to try it out for yourself, which is exactly what many users of NL5 have done. I look forward to hearing the positive feedback they will likely share soon. It’s important to note what to anticipate from NL5: it is not just another variation of SPICE, nor can it be considered a direct substitute. In certain applications, NL5 demonstrates significant advantages, while in others it performs adequately, and there are some areas where it may not be suitable at all. Ultimately, the versatility of NL5 makes it a compelling option for specific tasks within circuit simulation.

A dedicated solution for analyzing power integrity, signal integrity, and electromagnetic interference in integrated circuit packages and printed circuit boards, this tool addresses challenges within power delivery systems and high-speed channels found in electronic devices. SIwave is instrumental in modeling, simulating, and validating the high-speed channels and comprehensive power delivery systems prevalent in cutting-edge high-performance electronics. It proficiently extracts multi-gigabit SERDES interfaces and memory buses, ensuring compliance with product sign-off requirements across diverse designs. With its full wave extraction capabilities, SIwave meticulously assesses complete power distribution networks (PDN), enabling users to verify noise margins and meet impedance profiles through automated decoupling analysis, particularly in low-voltage applications. This comprehensive functionality positions SIwave as an essential asset for engineers striving for excellence in modern electronic design. Its ability to streamline the validation process significantly enhances design reliability and performance.

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.

GoldSim stands out as the leading software for Monte Carlo simulations, adept at dynamically modeling intricate systems across various fields such as engineering, science, and business. By facilitating decision-making and conducting risk analysis, GoldSim allows for the simulation of future performance while effectively quantifying the uncertainties and risks that are essential to understanding complex systems. Its versatility is recognized globally, with organizations utilizing GoldSim to assess and compare different designs, strategies, and policies to enhance decision-making and mitigate risks in an unpredictable environment. In particular, projects related to water resources and hydrological modeling often require the simulation of interconnected systems composed of numerous components, which may be inadequately defined. Typically, these hydrological systems are influenced by stochastic factors like precipitation, evaporation, and demand, presenting a landscape filled with uncertain processes, parameters, and events that complicate analysis. Thus, GoldSim proves to be an invaluable tool for navigating the complexities of these environmental challenges.

This tool seamlessly merges precision and efficiency within a comprehensive design framework, achieving simulation speeds that are 10-50 times quicker than SPICE for power supply designs. It encompasses all functionalities of SIMetrix Classic while maintaining the same graphical user interface, which includes a hierarchical schematic editor and a waveform viewer. It quickly identifies the steady state operating point of a switching system, eliminating the need to simulate initial transient conditions. Furthermore, it facilitates the conversion of SPICE transistor and diode models into SIMPLIS format by executing a SPICE simulation for parameter extraction. The advanced digital simulation library boasts a diverse array of digital functions, including counters, ADCs, DACs, and much more, ensuring that designers have the tools they need at their fingertips. This integration of features makes it an invaluable asset for anyone involved in power supply design and simulation.

LIQUi|> serves as a comprehensive software architecture and toolkit specifically designed for quantum computing applications. It features a programming language alongside optimization and scheduling algorithms, as well as quantum simulation capabilities. This tool enables the conversion of high-level quantum algorithms into the low-level machine instructions needed for quantum devices. The development of LIQUi|> is being spearheaded by the Quantum Architectures and Computation Group (QuArC) at Microsoft Research. QuArC has crafted this extensive software platform to facilitate the exploration and comprehension of various quantum protocols, algorithms, error correction methods, and devices. Additionally, LIQUi|> provides functionalities for simulating Hamiltonians, quantum circuits, stabilizer circuits, and noise models, while also accommodating client, service, and cloud-based operations. This comprehensive toolkit is an essential resource for researchers and developers venturing into the realm of quantum computing.

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

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.

Cirq is a Python library designed for creating, modifying, and optimizing quantum circuits, which can be executed on both quantum computers and simulators. It offers valuable abstractions tailored for the current generation of noisy intermediate-scale quantum computers, where understanding the hardware specifics is crucial for achieving optimal outcomes. The library includes integrated simulators that can manage both wave function and density matrix representations, capable of simulating noisy quantum channels through Monte Carlo methods or complete density matrix techniques. Additionally, Cirq is compatible with an advanced wavefunction simulator known as qsim, allowing users to replicate quantum hardware experiences through a quantum virtual machine. By utilizing Cirq, researchers can conduct experiments on Google's quantum processors, providing a platform for innovative exploration in quantum computing. For those interested in delving deeper, resources are available to learn about recent experiments and access the code needed to replicate these experiments independently.

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.

Utilizing the 3DEXPERIENCE® platform, SIMULIA provides advanced simulation tools that help users better understand and analyze our environment. The applications offered by SIMULIA streamline the assessment of material and product performance, reliability, and safety prior to the development of physical prototypes. These tools deliver robust simulations for various scenarios such as structures, fluids, multibody interactions, and electromagnetics, all while being seamlessly integrated with product data, even for complex assemblies. The comprehensive technology for modeling, simulation, and visualization is fully embedded within the 3DEXPERIENCE platform, which includes capabilities for process capture, publication, and reuse. By allowing simulation data, outcomes, and intellectual property to be linked to the platform, customers can maximize their current investment in simulation capabilities, transforming these assets into valuable resources that foster innovation for all users involved. This integration not only enhances workflow efficiency but also encourages collaborative advancements across different teams and projects.