IT career fact sheet

IT career fact sheet IT career fact sheetPosted June 11, 2014, by Andrea RiddellIT ResourcesSystems analyst sample resumeSystems analyst sample cover letterCareer Insider StoriesBrett Raven - RedBalloon Chief Technology OfficerInterested in becoming a?Management ConsultantMarketing OfficerProject ManagerSystems AdministratorHelp Desk OfficerPopular Career Searchesbasic it coursesfast track career in itit certification courses in demand melbournegov funded IT courses brisbanegovernment funded IT courses onlineIT CoursesBachelor of Cyber SecurityEnquire Online Enquire OnlineGraduate Diploma of Data ScienceEnquire Online Enquire OnlineBachelor of Applied Information TechnologyEnquire Online Enquire OnlineAssociate Degree of Applied Information TechnologyEnquire Online Enquire OnlineAndrea RiddellRelated ArticlesBrowse moreITWOMENNine reasons to get a job in ITNow has never been a better time to make the jump into the world of coding, hard drives and USB ports. The IT industry is calling .DesignDigital Media10 jobs that the internet createdThe internet may have made some occupations redundant but did you know it has created more jobs than it has made obsolete? This week Julia looks at some of the new roles that have been spun in the world wide web.Future trendsThe Revolution of Artificial Intelligence What is artificial intelligence? Whats the future of AI? Which countries are ahead in the AI race? What impacts does AI have on your industry? We answer all your questions in one handy infographic

FEA and the Question of Credibility

FEA and the Question of Credibility FEA and the Question of Credibility Finite Element Analysis (FEA) is designed to save money and time by computerizing engineering analysis. FEA is a digital way to test designs against predictable forces, to determine whether a design will fail and, if so, when and how the material will deform, snap, or collapse. As a central part of engineering analysis, FEA also helps ensure against risky under-design and costly over-design. Finite komponente analysis has migrated over the years from a purely academic pursuit into everyday product development. FEA does not eliminate the need for prototypes, but it can shorten the process. Often only one or two prototypes need to be built and tested before anything new goes into production. Digital prototyping also allows designers to quickly dig into mora design options. E Is for Element Models are built up from finite, discrete elementsanywhere from a few thousand to hundreds of millions. Hundreds of different elements cover most possible calculations of mechanical properties found in the real world. Elements include lines, shells, 2-D planar solids, planes (stress or strain), shear panels and membranes, 2-D axi-symmetrics, 3-D surfaces and solids, plates, beams, triangles, wedges, tetrahedrons and bricks, hexagons, mass, and general stiffness matrices. In addition to the geometric shapes, hundreds of other elements have been created for specific problemsfor pressure or bending, for example. Additional elements represent plastics, rubber, ceramics, concrete, masonry, aerospace composites, and other materials. Some of these elements are idealizations that embody a particular engineering concept. Some idealized elements have more than 100 nodes and as many as 11 degrees of freedom per node. Meshing converts design geometry into FEA elementsdigital Lego blocks. In FEA, mesh is the network of elements linked at their nodes and with loads properly applied. This is where calculations are done. The more dense the mesh, the more realistic and more accurate the solution. Even on the speediest hardware, very large FEA models may require days of nonstop number crunching. FEA calculates effects of loading at each node of every element with thousands or millions of simultaneous differential equations. Making it Credible The biggest challenge in FEA is validation, carefully chosen and closely monitored physical tests that confirm whether or not physical reality and virtual reality line up. A consensus among FEA analysts is that validation ensures that there are no hidden disconnects between the model and the physical testing, that correct physical properties are used, and that properties are analyzed accurately based on correct principles of physics. Simulations have become so incredibly comprehensive that it is no longer possible to establish confidence in these models by using simple engineering judgment or hand calculations. The physical tests are critical for credible analyse s. As in any other engineering analysis, FEA model builders often have to deal with unknowns such as exact loads on the exterior surfaces of modeled objects. The solution is straightforward Make sure that worst-case and best-case models are built and then err on the side of safety. According to its practitioners, FEA is useful wherever the risk of material failure or engineering error has serious consequencesany of the legal, regulatory and bottom-line ramifications of product failure. They also point out that credibility lies at the heart of the every simulation effort, FEA or otherwise. When the penalties of failure are great, spending $10,000 or $50,000 for FEA is easily justified. Adapted from The Question of Credibility by Jack Thornton, for Mechanical Engineering, May 2010. FEA does not eliminate the need for prototypes, but it can shorten the process. Often only one or two prototypes need to be built and tested before anything new goes into production.