Differential Equations Notes 110207
Question:
`q001. Solve the equation y ' = t^(3/2) tan(y) for the initial condition y(0) = pi/2.
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Question: `q002. We saw previously that the equation y ' = -.01 t y^2 has solutions of the form y = 1 / (-.005 t^2 - c). For negative values of c this solution has a vertical asymptote at t = sqrt(200 c), and is not defined at t = sqrt(200 c).
We can understand why this equation has vertical asymptotes if we plot the direction field. Plot the direction field defined by t values 0, 2, 4, 6, 8 and 10, and y values 0, 10, 20, 30, 40. Explain what happens when you sketch solution curves from various points of this grid.
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Question: `q003. The sort of thing that happened with the direction field of y = -.01 t y^2 cannot happen for a linear differential equation of the form y ' + p(t) y = 0, unless p(t) itself is undefined at a point. Explain why this is so.
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Question:
`q004. Write the equation ( y^2 cos(t) ) ' = 0 in the form f(t, y, y') = 0. (To do so, find the derivative of y^2 cos(t) and set it equal to zero).
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Show that this equation is solved by the function y for which y^2 cos(t) = c, where c is an arbitrary constant.
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Question: `q005. Show that the equation
dF = 0,
where F is a function F(t, y), is of the form
N(t,y) dt + M(t, y) dx = 0.
where N(t, y) = F_t and M(t, y) = F_y.
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Show furthermore than N_y = M_t.
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Question:
`q006. Show that the equation
( sqrt(y) - e^t cos(y) + t ) dt + (t / (2 sqrt(y) + e^t sin(y)) dy = 0
is of the form
N dt + M dy = 0, with N_y = M_t.
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Integrate N with respect to t, recalling that since y is treated as a constant, the integration constant can be any function f(y).
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Integrate M with respect to y, recalling that since t is treated as a constant, the integration constant can be any function g(t).
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Show that these integrals can be made equal by making a good choice of f(y) and g(t).
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Let F(t, y) be the common integral of the two functions.
Show that our equation is of the form dF = 0.
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Argue that the solution is therefore of the form F(t, y) = c, for a constant c.
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