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by exmadscientist
503 days ago
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It is not actually true that MLCC DC bias derating scales with voltage rating. The voltage rating itself actually has nothing to do with it. The correlation is with package size. (Package size and voltage rating are often loosely correlated (and were strongly correlated back in the day), which is where the misconception comes from.) The physical origin of the effect is electric field strength in the dielectric material; thicker dielectrics reduce the field strength, so you don't come as close to hitting the polarizability limit of the piezoelectric materials, at a given applied voltage. Voltage rating doesn't really show up in that analysis. If you don't believe me, poke around a bit in SimSurfing or similar. You should also notice that most capacitors are actually binned by voltage rating these days: a 16V part and a 50V part might be identically specified, but one's curves just cut off at 16V. I don't know if that's strictly binning or just testing, but it's pretty clear they're the same parts under the hood. |
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This statement used to be false (I used to design boards where I would bump the voltage rating to get better DC bias behavior), but it looks like the engineering behind these capacitors has changed "recently" (as in the last 10 years), and it is now mostly true.
Looking at Murata caps, for example:
1.0uF--uniformly 50% derating from 6-16V:
https://www.murata.com/en-us/products/productdetail?partno=G...
https://www.murata.com/en-us/products/productdetail?partno=G...
https://www.murata.com/en-us/products/productdetail?partno=G...
100nf--uniformly 2% derating from 6-16V:
https://www.murata.com/en-us/products/productdetail?partno=G...
https://www.murata.com/en-us/products/productdetail?partno=G...
https://www.murata.com/en-us/products/productdetail?partno=G...
Interesting. TIL.
Thanks for pointing that out.