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<exercise checkit-seed="0007" checkit-slug="AA5" checkit-title="Strategies for Solving IVPs">
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    <statement>
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        <p>
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For each ODE, describe an appropriate strategy to find its
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general solution, and the features of the ODE that make
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that strategy appropriate. (Do not fully solve these ODEs.)
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        </p>
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        <ol>
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                <li>
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                    <m>t^{2} {y'} + 2 \, t {y} - 2 \, t = 3 \, {y}^{2} {y'}</m>
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                </li>
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                <li>
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                    <m>-10 \, {y'} = 21 \, {y} + {y''}</m>
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                </li>
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                <li>
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                    <m>0 = 64 \, {y} - {y''} + 2 \, \delta\left(t - 7\right)</m>
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                </li>
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                <li>
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                    <m>-t {y'} - 10 \, t = -3 \, {y}</m>
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                </li>
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        </ol>
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  </statement>
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  <answer>
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        <ol>
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                <li>
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The ODE is exact, so it can be solved by finding a potential function.
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                </li>
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                <li>
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The ODE is linear homogeneous with constant coefficients, so it can be solved by using D-notation and factoring.
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                </li>
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                <li>
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The ODE is linear constant-coefficient with a discontinuous function, so it can be solved by using Laplace transforms.
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                </li>
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                <li>
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The ODE is linear first-order, so it can be solved by solving its homogeneous form and then using variation of parameters, or using an integrating factor.
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                </li>
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        </ol>
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  </answer>
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</exercise>
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