• \(f(0)=0\)
• \(\lim \limits _{x \to 10^+} f(x) = +\infty \)
• \(\lim \limits _{x \to 10^-} f(x) = -\infty \)
• \(f'(x)<0\) on \((-\infty ,0) \cup (6,10) \cup (10,14)\)
• \(f'(x)>0\) on \((0,6) \cup (14,\infty )\)
• \(f''(x)<0\) on \((4,10)\)
• \(f''(x)>0\) on \((-\infty ,4) \cup (10,\infty )\)

Try this on your own first, then either check with a friend or check the online version.

The first thing we will do is to plot the point \((0,0)\) and indicate the appropriate vertical asymptote due to the limit conditions. We also mark all of the places where \(f'\) or \(f''\) change sign.

Now we classify the behavior on each of the intervals:

• On \((-\infty , 0)\), \(f\) is increasing decreasing and concave updown
• On \((0, 4)\), \(f\) is increasing decreasing and concave updown
• On \((4, 6)\), \(f\) is increasing decreasing and concave updown
• On \((6, 10)\), \(f\) is increasing decreasing and concave updown
• On \((10, 14)\), \(f\) is increasing decreasing and concave updown
• On \((14, \infty )\), \(f\) is increasing decreasing and concave updown

Utilizing all of this information, we are forced to sketch something like the following:

• \(f(0)=1\)
• \(f(6)=2\)
• \(\lim \limits _{x \to 6^+} f(x) = 3\)
• \(\lim \limits _{x \to 6^-} f(x) = 1\)
• \(f'(x)<0\) on \((-\infty ,1)\)
• \(f'(x)>0\) on \((1,6)\)
• \(f'(x) = -2\) on \((6, \infty )\)
• \(f''(x)<0\) on \((2.5,5)\)
• \(f''(x)>0\) on \((-\infty ,2.5) \cup (5,6)\)

Try this on your own first, then either check with a friend or check the online version.

The first thing we will do is to plot the points \((0,1)\) and \((6,2)\), and the “holes” at \((6,3)\) and \((6,1)\) due to the limit conditions. We can immediately draw in what \(f\) looks like on \((6,\infty )\) since it is linear with slope \(2\), and must connect to the hole at \((6,2)\). We also mark all of the places where \(f'\) or \(f''\) change sign.

Now we classify the behavior on each of the intervals:

• On \((-\infty , 1)\), \(f\) is increasing decreasing and concave updown
• On \((1, 2.5)\), \(f\) is increasing decreasing and concave updown
• On \((2.5, 5)\), \(f\) is increasing decreasing and concave updown
• On \((5, 6)\), \(f\) is increasing decreasing and concave updown

Utilizing all of this information, we are forced to draw something like the following:

Assume \(f\) is continuous for all real numbers.