system engineering

Cisco Validated Designs (CVDs) present systems that are based on common use cases or engineering priorities.

Cisco Validated Designs (CVDs) present systems that are based on common use cases or engineering priorities. CVDs incorporate a broad set of technologies, features, and applications that address customer needs. Cisco engineers have comprehensively tested and documented each design in order to ensure faster, more reliable, and fully predictable deployment.

Cisco Validated Designs (CVDs) present systems that are based on common use cases or engineering priorities. CVDs incorporate a broad set of technologies, features, and applications that address customer needs. Cisco engineers have comprehensively tested and documented each design in order to ensure faster, more reliable, and fully predictable deployment.

Cisco® Validated Designs provide the foundation for systems design based on common use cases or current engineering system priorities. They incorporate a broad set of technologies, features, and applications to address customer needs. Cisco engineers have comprehensively tested and documented each Cisco Validated Design in order to ensure faster, more reliable, and fully predictable deployment. This design guide summary provides you with an overview of the Cisco Intelligent WAN Design Guide, the key technology, the use cases it provides, and additional and related resources.

Cisco Validated Designs (CVDs) provide the foundation for systems design based on common use cases or current engineering system priorities. They incorporate a broad set of technologies, features, and applications to address customer needs. Cisco engineers have comprehensively tested and documented each CVD in order to ensure faster, more reliable, and fully predictable deployment.

Cisco Validated Designs (CVDs) present systems that are based on common use cases or engineering priorities. CVDs incorporate a broad set of technologies, features, and applications that address customer needs. Cisco engineers have comprehensively tested and documented each design in order to ensure faster, more reliable, and fully predictable deployment.

Oracle has just announced a new microprocessor, and the servers and engineered system that are powered by it. The SPARC M8 processor fits in the palm of your hand, but it contains the result of years of co-engineering of hardware and software together to run enterprise applications with unprecedented speed and security. The SPARC M8 chip contains 32 of today’s most powerful cores for running Oracle Database and Java applications. Benchmarking data shows that the performance of these cores reaches twice the performance of Intel’s x86 cores. This is the result of exhaustive work on designing smart execution units and threading architecture, and on balancing metrics such as core count, memory and IO bandwidth. It also required millions of hours in testing chip design and operating system software on real workloads for database and Java. Having faster cores means increasing application capability while keeping the core count and software investment under control. In other words, a boost

Oracle has just announced a new microprocessor, and the servers and engineered system that are powered by it. The SPARC M8 processor fits in the palm of your hand, but it contains the result of years of co-engineering of hardware and software together to run enterprise applications with unprecedented speed and security. The SPARC M8 chip contains 32 of today’s most powerful cores for running Oracle Database and Java applications. Benchmarking data shows that the performance of these cores reaches twice the performance of Intel’s x86 cores. This is the result of exhaustive work on designing smart execution units and threading architecture, and on balancing metrics such as core count, memory and IO bandwidth. It also required millions of hours in testing chip design and operating system software on real workloads for database and Java. Having faster cores means increasing application capability while keeping the core count and software investment under control. In other words, a boost

If not, you are increasing the risk for costly, unplanned downtime. However, despite the importance of having a reliable flow of electricity, over half of building owners rely on reactive maintenance programs to care for their equipment. This means they wait until equipment fails completely before initiating corrective action, which is typically 3-4 times more costly than taking preventive measures. A good first step to go from being reactive to proactive is having a power system assessment performed to determine the current state and reliability of your electrical system. For more information on Power System Assessments, download our white paper, "Assessing the Health of a Facility's Electrical Power Distribution System".

If not, you are increasing the risk for costly, unplanned downtime. However, despite the importance of having a reliable flow of electricity, over half of building owners rely on reactive maintenance programs to care for their equipment. This means they wait until equipment fails completely before initiating corrective action, which is typically 3-4 times more costly than taking preventive measures. A good first step to go from being reactive to proactive is having a power system assessment performed. While often deemed expensive or unnecessary, the truth is power system assessments reveal opportunities to modernize, imiprove performance and help protect employees. To learn more, download our checklist, ""Ten Ways a Power System Assessment Can Save You Money"

Der Entwicklungsprozess wird mit zunehmender Komplexität mehr und mehr zum Schlüsselfaktor für Erfolg oder Misserfolg neuer Produkte. Wie aber bringt man Mechanik, Elektronik und Software optimal zusammen?

Der Entwicklungsprozess wird mit zunehmender Komplexität mehr und mehr zum Schlüsselfaktor für Erfolg oder Misserfolg neuer Produkte. Wie aber bringt man Mechanik, Elektronik und Software optimal zusammen?

Der Entwicklungsprozess wird mit zunehmender Komplexität mehr und mehr zum Schlüsselfaktor für Erfolg oder Misserfolg neuer Produkte. Wie aber bringt man Mechanik, Elektronik und Software optimal zusammen?

Power industries - including Nuclear, Fossil, Hydro, Wind and Geothermal - are susceptible to a variety of cyber threats which can wreak havoc on control systems. Management, engineering and IT must commit to a comprehensive approach that encompasses threat prevention, detection and elimination.

Learn: - What systems engineering is - How systems engineering can help you develop smart, connected products - How to expedite time-to-market, ensure business agility, and deliver high-quality smart products

This spotlight report examines: • How Manufacturing Operations Management (MOM) or Manufacturing Execution Systems (MES) are key enablers of data management and Digital Transformation. Companies can combine many other opportunities with manufacturing operations in a digital journey. • Product lifecycle management (PLM) as a high-value discipline to pair with MOM in discrete manufacturing, and the value of digital continuity across engineering, manufacturing operations, and supply chain. • A robust integration of MOM and PLM technologies and the advent of the Digital Twin (a virtual copy of the product and how it's made) to demonstrate maturity in Smart Manufacturing and the ability to make smart products in smart factories. The IIoT has opened up a world of opportunity for manufacturers. Take advantage of it.

This paper discusses some important considerations for A&D manufacturers in the context of enterprise information systems and how they can help in addressing five important areas of concern-compliance, control, communications, competitiveness, and cutting cost, waste and complexity.

Oracle has just announced a new microprocessor, and the servers and engineered system that are powered by it. The SPARC M8 processor fits in the palm of your hand, but it contains the result of years of co-engineering of hardware and software together to run enterprise applications with unprecedented speed and security. The SPARC M8 chip contains 32 of today’s most powerful cores for running Oracle Database and Java applications. Benchmarking data shows that the performance of these cores reaches twice the performance of Intel’s x86 cores. This is the result of exhaustive work on designing smart execution units and threading architecture, and on balancing metrics such as core count, memory and IO bandwidth. It also required millions of hours in testing chip design and operating system software on real workloads for database and Java. Having faster cores means increasing application capability while keeping the core count and software investment under control. In other words, a boost

Oracle has just announced a new microprocessor, and the servers and engineered system that are powered by it. The SPARC M8 processor fits in the palm of your hand, but it contains the result of years of co-engineering of hardware and software together to run enterprise applications with unprecedented speed and security. The SPARC M8 chip contains 32 of today’s most powerful cores for running Oracle Database and Java applications. Benchmarking data shows that the performance of these cores reaches twice the performance of Intel’s x86 cores. This is the result of exhaustive work on designing smart execution units and threading architecture, and on balancing metrics such as core count, memory and IO bandwidth. It also required millions of hours in testing chip design and operating system software on real workloads for database and Java. Having faster cores means increasing application capability while keeping the core count and software investment under control. In other words, a boost

Technology Principles for Architecting a Secure Messaging Environment

Aerospace and Defense companies delivering complex products in competitive markets must overcome many challenges to manage requirements throughout the product lifecycle. Among the most difficult challenges are integrating complex systems engineering processes, promoting collaboration among multiple engineering disciplines and enabling the sharing of intellectual property within globally dispersed teams. Companies seeking a way to efficiently manage product requirements can leverage a comprehensive product lifecycle management (PLM) solution to: • Effectively reuse intellectual property to reduce time to market • Increase product innovation • Improve overall traceability of requirements throughout the product lifecycle This paper will highlight the criteria needed for a comprehensive requirements management solution that incorporates PLM to offer customers a scalable, enterprise-grade solution.

The recent release of the Environmental Protection Agency (EPA) study on data center energy efficiency is adding fuel to the fire in the research and development of new ways to reduce energy use in centers. The findings, summarized on the EPA website, are staggering: Data centers consumed about 60 billion kilowatt-hours (kWh) in 2006, roughly 1.5 percent of total US electricity consumption -Energy consumption of servers and data centers has doubled in the past five years and is expected to almost double again in the next five years to more than 100 billion kWh, costing about $7.4 billion annually.

Cisco Validated Designs (CVDs) provide the foundation for systems design based on common use cases or current engineering system priorities.

Cisco Validated designs (CVds) provide the framework for systems design based on common use cases or current engineering system priorities.

Cisco Validated Designs (CVDs) present systems that are based on common use cases or engineering priorities. CVDs incorporate a broad set of technologies, features, and applications that address customer needs. Cisco engineers have comprehensively tested and documented each design in order to ensure faster, more reliable, and fully predictable deployment.