Math (Subject) GRE without Diff EQ

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The discussion centers on the challenges of preparing for the Math GRE without having taken a formal class in differential equations. The individual expresses concern about the impact of this on their graduate school applications but is reassured that self-study can effectively cover the necessary material. Key topics for the GRE include basic differential equations, separable equations, homogeneous equations, exact equations, and first-order and higher-order linear equations with constant coefficients. It is noted that the exam typically focuses on simpler problems that can be solved quickly, suggesting that in-depth topics like series solutions or Laplace transforms are unlikely to appear. Resources such as the Boyce and DiPrima textbook are recommended for practice and review. Overall, with targeted self-study, the individual is likely to be adequately prepared for the differential equations portion of the GRE.
jeffasinger
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I just realized I won't have the chance to take a class in differential equations before I have to submit my math graduate school applications, so there's no way I'll have the class beforehand. I've taken pretty much every other topic mentioned, and will review heavily on the calculus (it's been awhile), but how much will this matter?

What sort of Differential Equation questions are typical for the Math GRE? How difficult would it be to just self-teach myself that (small?) portion of Diff EQ?
 
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My school has a weekly math GRE prep session which I attend once in awhile. As far as I can tell there are almoswt no questions on differential equations that aren't seperable. This page seems to say the same thing http://http://math.scu.edu/~eschaefe/gre.html" . In addition you couldn't be asked to solve a system of DE's or do variation of parameters when you have 3 minutes a question. Still I'd look at an engineeering or physics book and read the basic intro to De's section. It certainly shouldn't take you much more then a week to cover this stuff (the harder stuff like series solutions/Laplace transforms etc.) are highly unlikely to be on the test.
 
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I asked basically the same question over a month ago and got no replies. From looking at Princeton Review, I gathered at least this much appears on the exam:

-Basic DE's (immediate integration)
-Solutions to f' = f, y'' + y = 0 (this was not explicitly in the text, but I figured everyone knows this)
-Separable DE's
-Homogeneous equations (the function is homogeneous)
-Exact equations
-Using integrating factor for non-exact equation (in particular two well-known types of integrating factors in this case, namely when (M_y - N_x)/N is a function of x alone and a similar case, where the DE is M*dx + N*dy = 0 and subscripts denote partial derivative wrt that variable)
-First-Order Linear Eqs.
-Higher-Order Linear Eqs. w/ Const. Coefficients

I would try to understand at least one of the well-known methods for finding a particular solution to higher order linear equations, which would probably be the only thing you actually have to learn. I recommend looking at the Boyce and Diprima text for practice, and ideally this should serve as a calculus refresher, as far as the computational aspects go. Good luck.
 
Thanks all,
It sounds like with a little self study I won't have a problem.
 

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