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Simulation – an

past 40. ‘Direct,’ ‘interactive,’ ‘generative,’ and ‘incremental’ are new words that will replace the phrase ‘card deck’ – one which most engineers grew up with and kids coming out of school are completely unfamiliar. Simulation will move from checking designs to generating optimum designs. It will move from a tedious process to get just one result, to a process that can interactively explore the entire design space – like a gamer explores the virtual space. It will move from days and hours, to minutes and seconds. It will move from handcraſted processes, which cannot be duplicated, to repeatable processes that will replace a lot of expensive and time consuming physical tests in a certification process. It will move from systems, parts, and material designs that are disjointed, to behaviour models working inside of behavioural system models throughout the supply chain. Tis is what the future will bring. In Clayton Christensen’s book Te


Innovator’s Dilemma, Christensen describes technology disruptions and maps them on an ‘S’ curve (see figure). Te theory is simple. New technology starts slow – generally below the performance of existing technologies – accelerates fast, then hits a peak and goes no further. If you think about writing, it has gone through at least four ‘S curves’ in the last 40 years – from manual to electric typewriters, to specialised hardware and soſtware machines,

utomotive and aerospace companies will see more change introduced in soſtware simulation in the next four years than they have seen in the

to soſtware running on any hardware device. Each one of these S curves started slow but very quickly leaped over the prior S curve in terms of performance. For simulation, we have been on our first 40 year-long S curve. Te major simulation codes that are running in industry today came to market around 40 years ago, and so the processes used by industry today were defined a very long time ago. In a March 2014 end-user survey of

respondents who use a broad range of simulation tools, the message was clear. It is time to jump the 40-year S curve of simulation with a new S curve. Results included:

Usability and learnability l 50 per cent+ – Simulation takes at least a month to learn

l 60 per cent+ – Lack the skills necessary to interpret the results

Process challenges l 55 per cent – Spend 30 per cent or

more time cleaning CAD geometry and meshing

l 67 per cent – Need 2-4 solver runs to obtain a converged solution

l 80 per cent – Require 3 or more load cycles

l 90 per cent – Desire to bring simulation earlier into the design cycle

Physics and fidelity l 50 per cent – Spend days to weeks

transferring linear FEA models to nonlinear FEA

l 83 per cent – Would benefit from a unified simulation environment

Supply chain collaboration l 4 per cent – Satisfied with quality of

simulation models received from suppliers Technology as an S-Curve 24 SCIENTIFIC COMPUTING WORLD

l 75 per cent – Rebuild supplier models l 80 per cent – See value in simulation models from suppliers

Dominic Gallello is president and CEO of MSC Software Corporation

@scwmagazine l

innovator’s dilemma Dominic Gallello believes that simulation is coming to the end of a 40-year cycle and change will be rapid in the future

What is required to create a new S curve is

an architectural change, a rearrangement in the way components relate to each other. For simulation, the traditional CAD, then mesh, then solve, then post process, will undergo a complete change. To smooth the handover between CAD and simulation, a change in the way components relate to each other is required. To smooth the handoff between models and solvers, a change in the way




components relate to each other is required. To smooth the handover between solvers and post processing, a change in the way components relate to each other is required. With these changes, we’ll see simulation generate an optimum CAD design instead of just checking it. When these components are re-arranged,

process times will speed up by a factor of 50, trade studies previously elusive to simulation because of slow performance will become near real time and optimised parts will be produced before a CAD model is ever built. Finally, simulation has been the domain of specialised analysts. Expect engineers (non-analysts) to broadly start using tools to predict performance or products, due to ease of learning and ease of use of the new environments that will come to market.

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