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by jacquesm
1645 days ago
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EEs tend to be pretty practical in the same sense that mechanical engineers are pretty practical: they build stuff in ways that they (think they) understand to give them as good a chance as producing something that works the first time around. But the devil is in the details and mechanical engineers have one huge advantage: they deal with stuff at a scale where getting it wrong will have visible consequences. An electrical engineer getting their assumptions about electric fields emanation wrong is going to have a difficult problem to solve, electric fields don't readily visualize and without a very solid understanding of the theory it is extremely easy to mess this up. This is one reason why people tend to be conservative, if you do it 'like it is usually done' then the chances of discovering new and potentially expensive ways to mess it up go down a bit. I once - long ago - rebuilt a transmitter that I had designed using 'regular' components in the air on a circuit board. It took 6 tries to get it perfect, and every time I learned about a new assumption that wasn't exactly spelled out anywhere but that really made a huge difference in how the circuit operated. The electrical schematic was identical every time, the only thing that changed was the topology in space. And the difference between iteration #1 and iteration #6 from a performance point of view was huge, much larger than you would have ever thought could be the consequence of the very subtle changes to the various trace geometries. No matter how much you know - or don't know - about the way electrical fields interact with each other be prepared to be surprised, this stuff is simply hard when your circuitry goes beyond a minimum level of complexity. Interesting tidbit: many years later when designing the windmill stator/rotor/coil assembly some of this knowledge came in quite handy. |
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