Alternatives to FieldView

Utilizing the distinctive and inherently dynamic Lattice Boltzmann-based physics, the PowerFLOW CFD solution conducts simulations that effectively replicate real-world scenarios. With the PowerFLOW suite, engineers can assess product performance at the early stages of design, before any prototypes are constructed—this is when alterations can have the most substantial effects on both design and budget. The PowerFLOW system seamlessly imports intricate model geometries and conducts aerodynamic, aeroacoustic, and thermal management simulations with high accuracy and efficiency. By automating domain discretization and turbulence modeling along with wall treatment, it removes the need for manual volume meshing and boundary layer meshing. Users can confidently execute PowerFLOW simulations using a large number of compute cores on widely utilized High Performance Computing (HPC) platforms, enhancing productivity and reliability in the simulation process. This capability not only accelerates product development timelines but also ensures that potential issues are identified and addressed early in the design phase.

Simr (formerly UberCloud) is revolutionizing the world of simulation operations with our flagship solution, Simulation Operations Automation (SimOps). Designed to streamline and automate complex simulation workflows, Simr enhances productivity, collaboration, and efficiency for engineers and scientists across various industries, including automotive, aerospace, biomedical engineering, defense, and consumer electronics. Our cloud-based infrastructure provides scalable and cost-effective solutions, eliminating the need for significant upfront investments in hardware. This ensures that our clients have access to the computational power they need, exactly when they need it, leading to reduced costs and improved operational efficiency. Simr is trusted by some of the world's leading companies, including three of the seven most successful companies globally. One of our notable success stories is BorgWarner, a Tier 1 automotive supplier that leverages Simr to automate its simulation environments, significantly enhancing their efficiency and driving innovation.

Kombyne™ represents a cutting-edge Software as a Service (SaaS) tool designed for high-performance computing (HPC) workflows, originally tailored for clients in sectors such as defense, automotive, aerospace, and academic research. This platform empowers users to access a diverse array of workflow solutions specifically for HPC computational fluid dynamics (CFD) tasks, encompassing features like on-the-fly extract generation, rendering capabilities, and simulation steering options. Users can benefit from interactive monitoring and control functionalities, all while ensuring minimal disruption to simulations and eliminating reliance on VTK. By employing extract workflows, the necessity for handling large files is significantly reduced, allowing for real-time visualization. The system incorporates an in-transit workflow that utilizes a distinct process to swiftly receive data from the solver code, enabling visualization and analysis without hindering the operation of the running solver. This specialized process, referred to as an endpoint, facilitates the direct output of extracts, cutting planes, or point samples useful for data science, in addition to rendering images. Furthermore, the Endpoint serves as a conduit to widely-used visualization software, enhancing the overall usability and integration of the tool within various workflows. With its versatile features and ease of use, Kombyne™ is set to revolutionize the way HPC tasks are managed and executed across multiple industries.

Metariver Technology Co., Ltd. develops innovative and creative computer-aided engineering (CAE) analysis S/W based upon the most recent HPC technology and S/W technologies including CUDA technology. We are changing the paradigm in CAE technology by using particle-based CAE technology, high-speed computation technology with GPUs, and CAE analysis software. Here is an introduction to our products. 1. Samadii-DEM: works with discrete element method and solid particles. 2. Samadii-SCIV (Statistical Contact In Vacuum): working with high vacuum system gas-flow simulation. 3. Samadii-EM (Electromagnetics) : For full-field interpretation 4. Samadii-Plasma: For Analysis of ion and electron behavior in an electromagnetic field. 5. Vampire (Virtual Additive Manufacturing System): Specializes in transient heat transfer analysis.

Simufact Additive is an advanced and adaptable software tool designed for simulating metal-based additive manufacturing techniques. Learn how to effectively utilize Simufact Additive to enhance your metal 3D printing and rapid prototyping efforts. By employing this software, you can greatly minimize the need for numerous test prints. Our objective is to furnish you with a solution that enables the production of additive manufacturing components with consistent dimensional accuracy on the first attempt. The multi-scale approach of Simufact Additive integrates the most effective methods into a singular software solution, ranging from a rapid mechanical technique to an intricate thermal-mechanical coupled transient analysis that offers exceptional precision in simulation results. Users can select the most suitable simulation method according to their specific requirements. Simufact Additive stands out as a specialized software solution focused solely on the simulation of additive manufacturing processes, which is evident in its streamlined operating framework. This focused approach not only enhances usability but also improves overall efficiency in the design and production workflow.

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

Amazon EC2 UltraClusters allow for the scaling of thousands of GPUs or specialized machine learning accelerators like AWS Trainium, granting users immediate access to supercomputing-level performance. This service opens the door to supercomputing for developers involved in machine learning, generative AI, and high-performance computing, all through a straightforward pay-as-you-go pricing structure that eliminates the need for initial setup or ongoing maintenance expenses. Comprising thousands of accelerated EC2 instances placed within a specific AWS Availability Zone, UltraClusters utilize Elastic Fabric Adapter (EFA) networking within a petabit-scale nonblocking network. Such an architecture not only ensures high-performance networking but also facilitates access to Amazon FSx for Lustre, a fully managed shared storage solution based on a high-performance parallel file system that enables swift processing of large datasets with sub-millisecond latency. Furthermore, EC2 UltraClusters enhance scale-out capabilities for distributed machine learning training and tightly integrated HPC tasks, significantly decreasing training durations while maximizing efficiency. This transformative technology is paving the way for groundbreaking advancements in various computational fields.

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.

The Lustre file system is a parallel, open-source file system designed to cater to the demanding requirements of high-performance computing (HPC) simulation environments often found in leadership class facilities. Whether you are part of our vibrant development community or evaluating Lustre as a potential parallel file system option, you will find extensive resources and support available to aid you. Offering a POSIX-compliant interface, the Lustre file system can efficiently scale to accommodate thousands of clients, manage petabytes of data, and deliver impressive I/O bandwidths exceeding hundreds of gigabytes per second. Its architecture includes essential components such as Metadata Servers (MDS), Metadata Targets (MDT), Object Storage Servers (OSS), Object Server Targets (OST), and Lustre clients. Lustre is specifically engineered to establish a unified, global POSIX-compliant namespace suited for massive computing infrastructures, including some of the largest supercomputing platforms in existence. With its capability to handle hundreds of petabytes of data storage, Lustre stands out as a robust solution for organizations looking to manage extensive datasets effectively. Its versatility and scalability make it a preferable choice for a wide range of applications in scientific research and data-intensive computing.

AWS Parallel Computing Service (AWS PCS) is a fully managed service designed to facilitate the execution and scaling of high-performance computing tasks while also aiding in the development of scientific and engineering models using Slurm on AWS. This service allows users to create comprehensive and adaptable environments that seamlessly combine computing, storage, networking, and visualization tools, enabling them to concentrate on their research and innovative projects without the hassle of managing the underlying infrastructure. With features like automated updates and integrated observability, AWS PCS significantly improves the operations and upkeep of computing clusters. Users can easily construct and launch scalable, dependable, and secure HPC clusters via the AWS Management Console, AWS Command Line Interface (AWS CLI), or AWS SDK. The versatility of the service supports a wide range of applications, including tightly coupled workloads such as computer-aided engineering, high-throughput computing for tasks like genomics analysis, GPU-accelerated computing, and specialized silicon solutions like AWS Trainium and AWS Inferentia. Overall, AWS PCS empowers researchers and engineers to harness advanced computing capabilities without needing to worry about the complexities of infrastructure setup and maintenance.

Warewulf is a cutting-edge cluster management and provisioning solution that has led the way in stateless node management for more than twenty years. This innovative system facilitates the deployment of containers directly onto bare metal hardware at an impressive scale, accommodating anywhere from a handful to tens of thousands of computing units while preserving an easy-to-use and adaptable framework. The platform offers extensibility, which empowers users to tailor default functionalities and node images to meet specific clustering needs. Additionally, Warewulf endorses stateless provisioning that incorporates SELinux, along with per-node asset key-based provisioning and access controls, thereby ensuring secure deployment environments. With its minimal system requirements, Warewulf is designed for straightforward optimization, customization, and integration, making it suitable for a wide range of industries. Backed by OpenHPC and a global community of contributors, Warewulf has established itself as a prominent HPC cluster platform applied across multiple sectors. Its user-friendly features not only simplify initial setup but also enhance the overall adaptability, making it an ideal choice for organizations seeking efficient cluster management solutions.

AWS High Performance Computing (HPC) services enable users to run extensive simulations and deep learning tasks in the cloud, offering nearly limitless computing power, advanced file systems, and high-speed networking capabilities. This comprehensive set of services fosters innovation by providing a diverse array of cloud-based resources, such as machine learning and analytics tools, which facilitate swift design and evaluation of new products. Users can achieve peak operational efficiency thanks to the on-demand nature of these computing resources, allowing them to concentrate on intricate problem-solving without the limitations of conventional infrastructure. AWS HPC offerings feature the Elastic Fabric Adapter (EFA) for optimized low-latency and high-bandwidth networking, AWS Batch for efficient scaling of computing tasks, AWS ParallelCluster for easy cluster setup, and Amazon FSx for delivering high-performance file systems. Collectively, these services create a flexible and scalable ecosystem that is well-suited for a variety of HPC workloads, empowering organizations to push the boundaries of what’s possible in their respective fields. As a result, users can experience greatly enhanced performance and productivity in their computational endeavors.

High-performance tasks associated with data-heavy AI, IoT, and HPC workloads have traditionally relied on costly, top-tier processors or accelerators like Graphics Processing Units (GPUs) to function optimally. Additionally, organizations utilizing cloud-based platforms for demanding computational tasks frequently encounter trade-offs that can be less than ideal. For instance, the outdated nature of processors and hardware in cloud infrastructures often fails to align with the latest software applications, while also raising concerns over excessive energy consumption and environmental implications. Furthermore, users often find certain features of cloud services to be cumbersome and challenging, which hampers their ability to create tailored cloud solutions that meet specific business requirements. This difficulty in achieving a perfect balance can lead to complications in identifying appropriate billing structures and obtaining adequate support for their unique needs. Ultimately, these issues highlight the pressing need for more adaptable and efficient cloud solutions in today's technology landscape.

Develop a hybrid storage solution that seamlessly integrates with your current network-attached storage (NAS) and Azure Blob Storage. This on-premises caching appliance enhances data accessibility whether it resides in your datacenter, within Azure, or traversing a wide-area network (WAN). Comprising both software and hardware, the Microsoft Azure FXT Edge Filer offers exceptional throughput and minimal latency, designed specifically for hybrid storage environments that cater to high-performance computing (HPC) applications. Utilizing a scale-out clustering approach, it enables non-disruptive performance scaling of NAS capabilities. You can connect up to 24 FXT nodes in each cluster, allowing for an impressive expansion to millions of IOPS and several hundred GB/s speeds. When performance and scalability are critical for file-based tasks, Azure FXT Edge Filer ensures that your data remains on the quickest route to processing units. Additionally, managing your data storage becomes straightforward with Azure FXT Edge Filer, enabling you to transfer legacy data to Azure Blob Storage for easy access with minimal latency. This solution allows for a balanced approach between on-premises and cloud storage, ensuring optimal efficiency in data management while adapting to evolving business needs. Furthermore, this hybrid model supports organizations in maximizing their existing infrastructure investments while leveraging the benefits of cloud technology.

AWS RoboMaker is a cloud-based simulation platform designed to support robotics developers by allowing them to efficiently run, scale, and automate simulations without the need to manage infrastructure themselves. This service provides a cost-effective approach for scaling simulation workloads and supports large-scale, parallel simulations through a single API call, while also enabling the creation of user-defined, randomized 3D virtual environments tailored to specific needs. Developers can enhance their workflows by conducting automated regression testing as part of continuous integration and continuous delivery pipelines, as well as train reinforcement learning models through numerous iterative trials. Furthermore, the platform facilitates the connection of multiple concurrent simulations to fleet management software, ensuring thorough and comprehensive testing processes. Integrating seamlessly with AWS machine learning, monitoring, and analytics services, AWS RoboMaker empowers robots to effectively stream data, navigate their surroundings, communicate, understand various inputs, and continuously learn. This integration not only enhances the capabilities of robots but also streamlines the overall development process, ultimately leading to more efficient and innovative robotic solutions.

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.

DIGIMU® creates digital polycrystalline microstructures that accurately reflect the material's heterogeneities, ensuring compliance with the intricate topological features of the microstructure. The boundary conditions applied to the Representative Elementary Volume (REV) mimic the experiences of a material point at the macroscopic level, particularly during the thermomechanical cycles relevant to that specific point. Utilizing a Finite Element formulation, the software simulates the various physical phenomena occurring in metal forming processes, such as recrystallization, grain growth, and Zener pinning caused by second phase particles. To enhance digital accuracy and minimize computation times, DIGIMU® employs advanced automated anisotropic meshing and remeshing adaptation technology, which allows for a detailed representation of grain boundaries while optimizing the number of elements used. This innovative approach not only streamlines the computational process but also improves the reliability of the simulations, making it a powerful tool for material scientists.

MantiumFlow offers a command line mode that allows users to specify the case location and select their desired template, after which it generates the case and notifies the user of any problems or confirms success. This method is the quickest way to create multiple cases efficiently. Alternatively, the graphical user interface (GUI) enhances the experience by enabling users to navigate through options with ease and view a list of customizable settings. The GUI also has the benefit of displaying imported CAD files, ensuring that all components are correctly positioned. Designed primarily for incompressible external aerodynamics simulations, MantiumFlow produces a report that includes plots illustrating convergence, forces, and various flow field visualizations. Additionally, the software automatically generates the mesh, incorporating a specific level of automated refinement region selection. For geometries that require rotation, users can implement a rotating wall boundary condition on the relevant surfaces for accurate modeling. This combination of features makes MantiumFlow a powerful tool for engineers and researchers in the field.

VSim is a sophisticated Multiphysics Simulation Software tailored for design engineers and research scientists who seek accurate solutions for complex challenges. Its exceptional integration of Finite-Difference Time-Domain (FDTD), Particle-in-Cell (PIC), and Charged Fluid (Finite Volume) methodologies ensures reliable outcomes across various applications, including plasma modeling. As a parallel software tool, VSim adeptly tackles large-scale problems, with simulations that execute rapidly thanks to algorithms optimized for high-performance computing environments. Renowned by researchers in over 30 countries and utilized by professionals across fields such as aerospace and semiconductor manufacturing, VSim guarantees results with verified accuracy that users can depend on. Developed by a dedicated group of computational scientists, Tech-X’s software has garnered thousands of citations in scientific literature, and VSim is prominently featured in many leading research institutions worldwide. Furthermore, its continued evolution reflects the commitment to meeting the ever-growing demands of modern scientific inquiry.

Enhance your decision-making process with Tecplot 360, the ultimate CFD post-processing tool. As more CFD simulations are conducted and grid sizes expand, the necessity for effective handling of large data sets and automated workflows becomes increasingly important. With Tecplot 360, you can reduce idle time and focus on discovering new insights. The software allows for seamless integration of XY, 2D, and 3D plots, giving you the flexibility to design visuals according to your specifications. Present your findings through stunning images and dynamic animations to captivate your audience. Simplify repetitive tasks using PyTecplot Python scripting to enhance productivity. Ensure that you never overlook important results while analyzing parametric data with the powerful Chorus tool. Access vast remote data securely through the SZL-Server client-server connection. Tecplot 360 supports a wide array of data formats including Tecplot, FLUENT, Plot3D, CGNS, OpenFOAM, FVCOM, VTU, and over 22 others related to CFD, FEA, and structural analysis. Additionally, you can efficiently report and compare multiple solutions in a multi-frame setup with various pages, allowing for comprehensive analysis and presentation. The software's versatility makes it an indispensable asset for any data-driven professional.

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.

Envision images backed by accurate and detailed data to enhance your development workflow. Accelerate the journey of your innovative imaging products to market. It offers a comprehensive model of an imaging system, incorporating lenses, sensors, and image and signal processors (ISPs) prior to production. This solution fosters improved collaboration among design teams. You can be assured that the products will function correctly once manufactured. With a Python interface, you can automate ImSym processes seamlessly. Tailor ISP functionalities through Python-scripted routines to meet specific needs. The platform provides a user-friendly, cohesive, and collaborative workflow that enhances overall user satisfaction. It yields reliable outcomes driven by the industry-leading CODE V and LightTools. ImSym combines various features to simulate an imaging system object utilizing a graphics input file. Its precision is bolstered by CODE V and LightTools, renowned as the most reliable design solutions for imaging and illumination optics. Ultimately, this integration empowers teams to innovate with confidence and efficiency.

NVIDIA Modulus is an advanced neural network framework that integrates the principles of physics, represented through governing partial differential equations (PDEs), with data to create accurate, parameterized surrogate models that operate with near-instantaneous latency. This framework is ideal for those venturing into AI-enhanced physics challenges or for those crafting digital twin models to navigate intricate non-linear, multi-physics systems, offering robust support throughout the process. It provides essential components for constructing physics-based machine learning surrogate models that effectively merge physics principles with data insights. Its versatility ensures applicability across various fields, including engineering simulations and life sciences, while accommodating both forward simulations and inverse/data assimilation tasks. Furthermore, NVIDIA Modulus enables parameterized representations of systems that can tackle multiple scenarios in real time, allowing users to train offline once and subsequently perform real-time inference repeatedly. As such, it empowers researchers and engineers to explore innovative solutions across a spectrum of complex problems with unprecedented efficiency.

Bright Cluster Manager offers a variety of machine learning frameworks including Torch, Tensorflow and Tensorflow to simplify your deep-learning projects. Bright offers a selection the most popular Machine Learning libraries that can be used to access datasets. These include MLPython and NVIDIA CUDA Deep Neural Network Library (cuDNN), Deep Learning GPU Trainer System (DIGITS), CaffeOnSpark (a Spark package that allows deep learning), and MLPython. Bright makes it easy to find, configure, and deploy all the necessary components to run these deep learning libraries and frameworks. There are over 400MB of Python modules to support machine learning packages. We also include the NVIDIA hardware drivers and CUDA (parallel computer platform API) drivers, CUB(CUDA building blocks), NCCL (library standard collective communication routines).

The NVIDIA HPC Software Development Kit (SDK) offers a comprehensive suite of reliable compilers, libraries, and software tools that are crucial for enhancing developer efficiency as well as the performance and adaptability of HPC applications. This SDK includes C, C++, and Fortran compilers that facilitate GPU acceleration for HPC modeling and simulation applications through standard C++ and Fortran, as well as OpenACC® directives and CUDA®. Additionally, GPU-accelerated mathematical libraries boost the efficiency of widely used HPC algorithms, while optimized communication libraries support standards-based multi-GPU and scalable systems programming. The inclusion of performance profiling and debugging tools streamlines the process of porting and optimizing HPC applications, and containerization tools ensure straightforward deployment whether on-premises or in cloud environments. Furthermore, with compatibility for NVIDIA GPUs and various CPU architectures like Arm, OpenPOWER, or x86-64 running on Linux, the HPC SDK equips developers with all the necessary resources to create high-performance GPU-accelerated HPC applications effectively. Ultimately, this robust toolkit is indispensable for anyone looking to push the boundaries of high-performance computing.

The Elastic Fabric Adapter (EFA) serves as a specialized network interface for Amazon EC2 instances, allowing users to efficiently run applications that demand high inter-node communication at scale within the AWS environment. By utilizing a custom-designed operating system (OS) that circumvents traditional hardware interfaces, EFA significantly boosts the performance of communications between instances, which is essential for effectively scaling such applications. This technology facilitates the scaling of High-Performance Computing (HPC) applications that utilize the Message Passing Interface (MPI) and Machine Learning (ML) applications that rely on the NVIDIA Collective Communications Library (NCCL) to thousands of CPUs or GPUs. Consequently, users can achieve the same high application performance found in on-premises HPC clusters while benefiting from the flexible and on-demand nature of the AWS cloud infrastructure. EFA can be activated as an optional feature for EC2 networking without incurring any extra charges, making it accessible for a wide range of use cases. Additionally, it seamlessly integrates with the most popular interfaces, APIs, and libraries for inter-node communication needs, enhancing its utility for diverse applications.

Kao Data stands at the forefront of the industry, innovating in the creation and management of data centres specifically designed for artificial intelligence and cutting-edge computing. Our platform, inspired by hyperscale models and tailored for industrial use, offers clients a secure, scalable, and environmentally friendly environment for their computing needs. Based at our Harlow campus, we support a diverse range of mission-critical high-performance computing projects, establishing ourselves as the UK's top choice for demanding, high-density, GPU-driven computing solutions. Additionally, with swift integration options available for all leading cloud providers, we enable the realization of your hybrid AI and HPC aspirations seamlessly. By prioritizing sustainability and performance, we are not just meeting current demands but also shaping the future of computing infrastructure.

HPE Performance Cluster Manager (HPCM) offers a cohesive system management solution tailored for Linux®-based high-performance computing (HPC) clusters. This software facilitates comprehensive provisioning, management, and monitoring capabilities for clusters that can extend to Exascale-sized supercomputers. HPCM streamlines the initial setup from bare-metal, provides extensive hardware monitoring and management options, oversees image management, handles software updates, manages power efficiently, and ensures overall cluster health. Moreover, it simplifies the scaling process for HPC clusters and integrates seamlessly with numerous third-party tools to enhance workload management. By employing HPE Performance Cluster Manager, organizations can significantly reduce the administrative burden associated with HPC systems, ultimately leading to lowered total ownership costs and enhanced productivity, all while maximizing the return on their hardware investments. As a result, HPCM not only fosters operational efficiency but also supports organizations in achieving their computational goals effectively.

The NVIDIA DGX Cloud provides an AI infrastructure as a service that simplifies the deployment of large-scale AI models and accelerates innovation. By offering a comprehensive suite of tools for machine learning, deep learning, and HPC, this platform enables organizations to run their AI workloads efficiently on the cloud. With seamless integration into major cloud services, it offers the scalability, performance, and flexibility necessary for tackling complex AI challenges, all while eliminating the need for managing on-premise hardware.

Moab®, HPC Suite automates the management, monitoring, reporting, and scheduling of large-scale HPC workloads. Its intelligence engine, which is patent-pending, uses multi-dimensional policies to optimize workload start times and run time on different resources. These policies balance high utilization goals and throughput with competing workload priorities, SLA requirements, and thus accomplish more work in less time and in a better priority order. Moab HPC Suite maximizes the value and use of HPC systems, while reducing complexity and management costs.

TotalView debugging software offers essential tools designed to expedite the debugging, analysis, and scaling of high-performance computing (HPC) applications. This software adeptly handles highly dynamic, parallel, and multicore applications that can operate on a wide range of hardware, from personal computers to powerful supercomputers. By utilizing TotalView, developers can enhance the efficiency of HPC development, improve the quality of their code, and reduce the time needed to bring products to market through its advanced capabilities for rapid fault isolation, superior memory optimization, and dynamic visualization. It allows users to debug thousands of threads and processes simultaneously, making it an ideal solution for multicore and parallel computing environments. TotalView equips developers with an unparalleled set of tools that provide detailed control over thread execution and processes, while also offering extensive insights into program states and data, ensuring a smoother debugging experience. With these comprehensive features, TotalView stands out as a vital resource for those engaged in high-performance computing.

The Intel® Tiber™ AI Cloud serves as a robust platform tailored to efficiently scale artificial intelligence workloads through cutting-edge computing capabilities. Featuring specialized AI hardware, including the Intel Gaudi AI Processor and Max Series GPUs, it enhances the processes of model training, inference, and deployment. Aimed at enterprise-level applications, this cloud offering allows developers to create and refine models using well-known libraries such as PyTorch. Additionally, with a variety of deployment choices, secure private cloud options, and dedicated expert assistance, Intel Tiber™ guarantees smooth integration and rapid deployment while boosting model performance significantly. This comprehensive solution is ideal for organizations looking to harness the full potential of AI technologies.

Qlustar presents an all-encompassing full-stack solution that simplifies the setup, management, and scaling of clusters while maintaining control and performance. It enhances your HPC, AI, and storage infrastructures with exceptional ease and powerful features. The journey begins with a bare-metal installation using the Qlustar installer, followed by effortless cluster operations that encompass every aspect of management. Experience unparalleled simplicity and efficiency in both establishing and overseeing your clusters. Designed with scalability in mind, it adeptly handles even the most intricate workloads with ease. Its optimization for speed, reliability, and resource efficiency makes it ideal for demanding environments. You can upgrade your operating system or handle security patches without requiring reinstallations, ensuring minimal disruption. Regular and dependable updates safeguard your clusters against potential vulnerabilities, contributing to their overall security. Qlustar maximizes your computing capabilities, ensuring peak efficiency for high-performance computing settings. Additionally, its robust workload management, built-in high availability features, and user-friendly interface provide a streamlined experience, making operations smoother than ever before. This comprehensive approach ensures that your computing infrastructure remains resilient and adaptable to changing needs.

NVIDIA GPU Cloud (NGC) serves as a cloud platform that harnesses GPU acceleration for deep learning and scientific computations. It offers a comprehensive catalog of fully integrated containers for deep learning frameworks designed to optimize performance on NVIDIA GPUs, whether in single or multi-GPU setups. Additionally, the NVIDIA train, adapt, and optimize (TAO) platform streamlines the process of developing enterprise AI applications by facilitating quick model adaptation and refinement. Through a user-friendly guided workflow, organizations can fine-tune pre-trained models with their unique datasets, enabling them to create precise AI models in mere hours instead of the traditional months, thereby reducing the necessity for extensive training periods and specialized AI knowledge. If you're eager to dive into the world of containers and models on NGC, you’ve found the ideal starting point. Furthermore, NGC's Private Registries empower users to securely manage and deploy their proprietary assets, enhancing their AI development journey.

Covalent's innovative serverless HPC framework facilitates seamless job scaling from personal laptops to high-performance computing and cloud environments. Designed for computational scientists, AI/ML developers, and those requiring access to limited or costly computing resources like quantum computers, HPC clusters, and GPU arrays, Covalent serves as a Pythonic workflow solution. Researchers can execute complex computational tasks on cutting-edge hardware, including quantum systems or serverless HPC clusters, with just a single line of code. The most recent update to Covalent introduces two new feature sets along with three significant improvements. Staying true to its modular design, Covalent now empowers users to create custom pre- and post-hooks for electrons, enhancing the platform's versatility for tasks ranging from configuring remote environments (via DepsPip) to executing tailored functions. This flexibility opens up a wide array of possibilities for researchers and developers alike, making their workflows more efficient and adaptable.

High-performance computing (HPC) serves as a fundamental element for applications in AI, machine learning, and deep learning. The Intel® oneAPI HPC Toolkit (HPC Kit) equips developers with essential tools to create, analyze, enhance, and expand HPC applications by utilizing the most advanced methods in vectorization, multithreading, multi-node parallelization, and memory management. This toolkit is an essential complement to the Intel® oneAPI Base Toolkit, which is necessary to unlock its complete capabilities. Additionally, it provides users with access to the Intel® Distribution for Python*, the Intel® oneAPI DPC++/C++ compiler, a suite of robust data-centric libraries, and sophisticated analysis tools. You can obtain everything needed to construct, evaluate, and refine your oneAPI projects at no cost. By signing up for an Intel® Developer Cloud account, you gain 120 days of access to the latest Intel® hardware—including CPUs, GPUs, FPGAs—and the full suite of Intel oneAPI tools and frameworks. This seamless experience requires no software downloads, no configuration processes, and no installations, making it incredibly user-friendly for developers at all levels.

AWS ParallelCluster is a free, open-source tool designed for efficient management and deployment of High-Performance Computing (HPC) clusters within the AWS environment. It streamlines the configuration of essential components such as compute nodes, shared filesystems, and job schedulers, while accommodating various instance types and job submission queues. Users have the flexibility to engage with ParallelCluster using a graphical user interface, command-line interface, or API, which allows for customizable cluster setups and oversight. The tool also works seamlessly with job schedulers like AWS Batch and Slurm, making it easier to transition existing HPC workloads to the cloud with minimal adjustments. Users incur no additional costs for the tool itself, only paying for the AWS resources their applications utilize. With AWS ParallelCluster, users can effectively manage their computing needs through a straightforward text file that allows for the modeling, provisioning, and dynamic scaling of necessary resources in a secure and automated fashion. This ease of use significantly enhances productivity and optimizes resource allocation for various computational tasks.

Design, oversee, operate, and enhance high-performance computing (HPC) and large-scale compute clusters seamlessly. Implement comprehensive clusters and additional resources, encompassing task schedulers, computational virtual machines, storage solutions, networking capabilities, and caching systems. Tailor and refine clusters with sophisticated policy and governance tools, which include cost management, integration with Active Directory, as well as monitoring and reporting functionalities. Utilize your existing job scheduler and applications without any necessary changes. Empower administrators with complete authority over job execution permissions for users, in addition to determining the locations and associated costs for running jobs. Benefit from integrated autoscaling and proven reference architectures suitable for diverse HPC workloads across various sectors. CycleCloud accommodates any job scheduler or software environment, whether it's proprietary, in-house solutions or open-source, third-party, and commercial software. As your requirements for resources shift and grow, your cluster must adapt accordingly. With scheduler-aware autoscaling, you can ensure that your resources align perfectly with your workload needs while remaining flexible to future changes. This adaptability is crucial for maintaining efficiency and performance in a rapidly evolving technological landscape.

Amazon EC2 P4d instances are designed for optimal performance in machine learning training and high-performance computing (HPC) applications within the cloud environment. Equipped with NVIDIA A100 Tensor Core GPUs, these instances provide exceptional throughput and low-latency networking capabilities, boasting 400 Gbps instance networking. P4d instances are remarkably cost-effective, offering up to a 60% reduction in expenses for training machine learning models, while also delivering an impressive 2.5 times better performance for deep learning tasks compared to the older P3 and P3dn models. They are deployed within expansive clusters known as Amazon EC2 UltraClusters, which allow for the seamless integration of high-performance computing, networking, and storage resources. This flexibility enables users to scale their operations from a handful to thousands of NVIDIA A100 GPUs depending on their specific project requirements. Researchers, data scientists, and developers can leverage P4d instances to train machine learning models for diverse applications, including natural language processing, object detection and classification, and recommendation systems, in addition to executing HPC tasks such as pharmaceutical discovery and other complex computations. These capabilities collectively empower teams to innovate and accelerate their projects with greater efficiency and effectiveness.

Create dependable and optimized code that delivers accurate results across various Server and HPC architectures, utilizing the latest compilers and C++ standards tailored for Intel, 64-bit Arm, AMD, OpenPOWER, and Nvidia GPU platforms. Arm Forge integrates Arm DDT, a premier debugger designed to streamline the debugging process of high-performance applications, with Arm MAP, a respected performance profiler offering essential optimization insights for both native and Python HPC applications, along with Arm Performance Reports that provide sophisticated reporting features. Both Arm DDT and Arm MAP can also be used as independent products, allowing flexibility in application development. This package ensures efficient Linux Server and HPC development while offering comprehensive technical support from Arm specialists. Arm DDT stands out as the preferred debugger for C++, C, or Fortran applications that are parallel or threaded, whether they run on CPUs or GPUs. With its powerful and user-friendly graphical interface, Arm DDT enables users to swiftly identify memory errors and divergent behaviors at any scale, solidifying its reputation as the leading debugger in the realms of research, industry, and academia, making it an invaluable tool for developers. Additionally, its rich feature set fosters an environment conducive to innovation and performance enhancement.

The convergence of high-performance computing (HPC) and machine learning is placing unprecedented requirements on storage solutions, as the input/output demands of these two distinct workloads diverge significantly. This shift is occurring at this very moment, with a recent analysis from the independent firm Intersect360 revealing that a striking 63% of current HPC users are actively implementing machine learning applications. Furthermore, Hyperion Research projects that, if trends continue, public sector organizations and enterprises will see HPC storage expenditures increase at a rate 57% faster than HPC compute investments over the next three years. Reflecting on this, Seymour Cray famously stated, "Anyone can build a fast CPU; the trick is to build a fast system." In the realm of HPC and AI, while creating fast file storage may seem straightforward, the true challenge lies in developing a storage system that is not only quick but also economically viable and capable of scaling effectively. We accomplish this by integrating top-tier parallel file systems into HPE's parallel storage solutions, ensuring that cost efficiency is a fundamental aspect of our approach. This strategy not only meets the current demands of users but also positions us well for future growth.

Amazon's Elastic Compute Cloud (EC2) offers P5 instances that utilize NVIDIA H100 Tensor Core GPUs, alongside P5e and P5en instances featuring NVIDIA H200 Tensor Core GPUs, ensuring unmatched performance for deep learning and high-performance computing tasks. With these advanced instances, you can reduce the time to achieve results by as much as four times compared to earlier GPU-based EC2 offerings, while also cutting ML model training costs by up to 40%. This capability enables faster iteration on solutions, allowing businesses to reach the market more efficiently. P5, P5e, and P5en instances are ideal for training and deploying sophisticated large language models and diffusion models that drive the most intensive generative AI applications, which encompass areas like question-answering, code generation, video and image creation, and speech recognition. Furthermore, these instances can also support large-scale deployment of high-performance computing applications, facilitating advancements in fields such as pharmaceutical discovery, ultimately transforming how research and development are conducted in the industry.

Simright Simulator allows users to import CAD models and perform structural analysis directly in a web browser, making it highly user-friendly. Even those without any prior experience in CAE analysis can swiftly carry out simulations. This tool is capable of addressing intricate structural challenges across various industries through an online platform. By utilizing CAE technology, it significantly lowers the expenses associated with physical experiments, empowering users to make more informed decisions. Moreover, its accessibility ensures that more individuals can leverage advanced analysis capabilities, further enhancing productivity and innovation.

Tidy3D, developed by Flexcompute, is an incredibly swift electromagnetic (EM) solver that utilizes the finite-difference time-domain (FDTD) technique. Its remarkable speed stems from the efficient co-design of both its software and hardware, allowing it to perform simulations significantly quicker than competing EM solvers. This unparalleled speed enables users to tackle problems that span hundreds of wavelengths, a task that traditional methods often struggle to handle effectively. Consequently, Tidy3D opens up new possibilities for researchers and engineers dealing with complex electromagnetic challenges.

Tecplot RS is a comprehensive visualization and analysis tool specifically designed for professionals in the oil and gas reservoir engineering field. It streamlines the handling and analysis of reservoir simulation data by offering detailed XY plots, 2D cross-sections, and 3D grid visualizations. By allowing users to import data from multiple simulation platforms, it helps in organizing outcomes, validating models, and sharing insights effectively among team members. The latest updates, including the 2023 R1 release, have introduced improvements that enhance the evaluation of history match quality through the ability to create selection sets based on deviation bands. Furthermore, the software has expanded its capabilities by incorporating the visualization of negative values in stamp plots, which is crucial for examining fluid behavior patterns within reservoirs. With an intuitive interface, Tecplot RS promotes a quick adaptation process for new users, alongside providing comprehensive technical support and complimentary online training resources. This approach not only fosters user confidence but also encourages collaborative efforts in analyzing complex reservoir data.