John said:
But follower amplifiers that drive big, slow, nonlinear devices have
all those same problems. Slow is just not as slow. When I first got
into process control, it seemed very strange, because I was unfamiliar
with the jargon. Then I realized that I have been using oscilloscopes
to study amplifiers doing all the things process control was doing,
except that now, I could have a cup of coffee while the dynamics
settled instead of it all happening in microseconds. but the
principles are just the same. Gain bandwidth product, phase shift,
slew rate limits, output nonlinearity, recovery from output overdrive,
etc. all there.
When I saw the Star Trek episode about the people who moved so fast
that they were invisible, I realized that they was how I felt while
tuning a control loop.
I don't disagree that there are lots of similarities, or that there's a lot
of jargon in control system design that seems intended to preserve job
security rather than make concepts clear. (There's a lot of that in some
optics disciplines too--it isn't just an EE problem. Not to mention all of
anthropology.) If I'm designing e.g. a laser temperature controller, I use
Bode plots: one for each of several representative choices of ambient
temperature and thermal forcing. PLL design with nonlinear tuning is
similar. Not everything is that simple, however.
Lots of control systems have to work in situations where an ugly settling
transient will cause destruction--from burned cookies and broken drive belts
to loss of life and property. There are very few purely electronic
situations (i.e. other than driving mechanical devices or large magnets)
where a poor transient response is that serious.
Ordinarily, with an amplifier driving a speaker, say, you can have a few pops
and bangs, but no great harm is done, and they can be tuned out during
debugging. The nonlinearity is of a simple and intuitive sort, and there is
no complex coupling. There is also usually no external forcing, unlike e.g.
a motor controller which may have very different loads at different times.
It isn't possible to test every situation, and it's the ones we haven't
thought about that will turn round and bite us in the backside. Systems that
are uncoupled during normal operation, but become coupled due to faults and
transients, are a common source of this.
Cheers,
Phil Hobbs