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\begin{frame}
  \frametitle{Antiderivatives / Integrals}

  Near the surface of the earth, the gravitational force
  produces a downward acceleration of approximately \alert{$9.8\text{m}/\text{s}^2$} (or \alert{$32\text{ft}/\text{s}^2$}).
  \pause
  
  \begin{exampleblock}{}
    A ball is thrown upward with a speed of $48\text{ft}/\text{s}$ 
    from the edge of cliff $432$ft above ground.
    When does the ball reach its maximum height?
    When does it hit the ground?
    \pause\medskip
    
    Let $s(t)$ be the distance above the ground, and $v(t)$ the velocity:\pause\vspace{-.5ex} 
    \begin{talign}
      a(t) &= \mpause[1]{-32} \\
      \mpause{v(t) &= }\mpause{-32t} \mpause{+ C} \hspace{1cm}\mpause{v(0) = C = 48} \\
      \mpause{s(t) &= }\mpause{-16t^2} \mpause{+ 48t} \mpause{+ D} \hspace{1cm}\mpause{s(0) = D = 432}
    \end{talign}
    \pause\pause\pause\pause\pause\pause\pause\pause\pause\pause\pause
    The ball reaches the maximal height when \pause\vspace{-.5ex} 
    \begin{talign}
      v(t) = 0 \mpause[1]{= -32t + 48} \mpause{\text{, that is, after $t = 1.5$ seconds}}
    \end{talign}
    \pause\pause\pause
    The ball hits the ground when\vspace{-.5ex} 
    \begin{talign}
      s(t) = 0 \mpause[1]{= -16t^2 + 48t + 432} \mpause{\;\iff\; t^2 - 3t - 27 = 0}
    \end{talign}\vspace{-2.5ex} 
    \pause\pause\pause
    
    We reject the negative solution, and find $t = 3/2 + 3/2\cdot \sqrt{13}$.
  \end{exampleblock} 
\end{frame}