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<exercise masterit-seed="9588" masterit-slug="X3" masterit-name="Existence/uniqueness theorem for first-order IVPs">
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  <statement>
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    <p>
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      Explain what the Existence and Uniqueness Theorem for First Order IVPs
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      guarantees about the existence and uniqueness of solutions for the following
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      IVP.
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    </p>
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    <me>
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      y'= 5 \, {\left(2 \, {y} + 2 \, t + 6\right)}^{\frac{4}{3}} \hspace{2em}
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      x( -6 )= 3 </me>
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  </statement>
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  <answer>
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    <p><m>F(t,y)= 5 \, {\left(2 \, {y} + 2 \, t + 6\right)}^{\frac{4}{3}} </m> is continuous at and nearby the
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      initial value so a solution exists for a nearby interval.
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      </p>
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    <p><m>F_y= \frac{40}{3} \, {\left(2 \, {y} + 2 \, t + 6\right)}^{\frac{1}{3}} </m> is continous
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              at and nearby the initial value so the solution is unique for
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              a nearby interval.
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            </p>
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  </answer>
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</exercise>
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