>
> Interesting story --
>
> For some of the mechanics of working problems in grad school, I
> still would often go back to my original notes from Richard
> Rand's classes at Cornell.   He is now known as an absolutely
> legendary educator now, but back then he was just another professor
> -- whose lectures just happened to be gripping, fascinating...
> almost unforgettable.  I eventually got rid of my record collection,
> but I sure hung on to those course notes, even after ditching the
> course textbooks.
>
> When I started graduate school at Chicago in Geophysics, I'd
> come out of a full 3 years of engineering math from Rand,
> including a graduate level courses that were weeding-out
> courses for physics grad students (I got a B) as an engineering
> undergraduate -- so in my first year at Chicago, I decided to
> sign up for what looked like the equivalent  graduate level
> courses in differential equations...for review.
>
> My grad advisor in our "get to know your faculty advisor and
> choose your courses" meeting thought this was overly ambitious
> and suggested I take "at least a course in *calculus.*"
>
> I pointed out that I'd done that in uh, high school.  He countered
> (definitively revealing that he'd not even read my transcript)
> "well that was a long time ago."  When I pointed out that I'd
> taken half a dozen engineering mathematics and physics courses
> that required calculus as a prerequisite, and used calculus
> almost continually, he stiffened and answered that "Mathematics is
> Different Here at Chicago."  (!!!) So I was like, "Oh what, you
> mean like 2+2=5 here?"
>
> He suggested a compromise whereby I'd sign up for sophomore-level
> complex analysis first quarter and ODE's second.  I figured this
> one wasn't worth fighting, and besides I could use the easy "A"
> if I didn't get too bored in the mean time.
>
> In practice, I was pleasantly surprised.  Whereas my
> engineering math courses had focussed primarily on technique,
> the mechanics of solving specific problems, and I could do
> Schwartz-Christoffel Transforms in my sleep already --these
> courses at Chicago focussed almost exclusively on proving a
> variety of properties of functions in the complex plane, i.e.
> analytic functions vs piecewise continuous functions, contour
> integration and so forth. In other words, it was complex *analysis*
> based on Ahlfors' text, not Complex Functions based on, say,
> Church.  What had previously seemed to be a chore with some
> incomprehensible beauty behind it, was now was something truly
> beautiful I was getting the tools to actually take apart and
> put back together, lectures from people with some real insight
> and understanding.
>
> ODEs and PDEs were even better in that regard, the ODEs course
> being based on Birkhoff and Gian-Carlo Rota's text, which is
> so beautifully written, it reads more like an exciting novel
> in places, *particularly* the proofs.  I'd been through Green's
> functions at least 3 times in different courses, for example,
> and again, could blow through the problem sets -- but it was
> just symbol manipulation.  It never even occured to me to even
> ask *why* Green's functions gave you the particular solution.
> It was just the technique you applied when you had a forcing
> function, and it worked.
>
> So one night, I'm studying for the midterm, and get sidetracked
> reading Gian-Carlo's one-page proof on Green's functions.  He
> actually drew me in to the story, when I "should have been
> studying" in the only way I knew how back then: working problems
> (in this case correcting some of the mistakes in Birkhoff and Rota).
> I thought for sure I was going to blow the exam, but this proof was
> cool and so interesting and so clearly written -- that I was
> able to reproduce the proof on the exam the next day...and I
> was the only one in the class able to do that.  So what I thought
> was "being sidetracked" -- actually taking an interest in the
> material for its own sake rather than chugging through that
> odious chore called math homework -- turned out to be a more
> effective study technique as well as a whole lot more fun.
>
> I had amost the same experience with a proof of the uniqueness
> and completeness of Fourier Series in PDEs, which Chicago taught
> from Weinberger's text.
>
> That first year at Chicago, math went from being a Beautiful BFJ
> to something even more beautiful and engaging -- like great art.
>
> When I was working through Guckenheimer and Holmes on my own
> (there wasn't a course at Chicago that used it) I used Hirsch and
> Smale as my ODEs reference rather than Birkhoff and Rota, because
> Hirsch and Smale uses the same notation and way of expressing
> things (Guckenheimer was Smale's student, after all).
>
> The nice thing about these classics is that you can go back to them and
> re-read them like a good novel.  They're incredibly enjoyable as well
> as merely useful.
>
> Some of these are really expensive these days, but  I think most of
> them are on the bookshelf at SFI:
>
> Complex Analysis:
> Ahlfors
>

>
> Cheryl
>
>
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