Lab 5
Objectives:
1. Solidify understanding of the connections between the shape of a function and the sign of its first and second derivatives,
2. Use these understandings to identify absolute and local extrema, and to explore families of functions
3. Review the connections between asymptotes and limits,
4.
<Text-field style="Text" foreground="[0,128,0]" bold="true" size="18" layout="Heading 1"><Font bold="true" size="18" foreground="[0,128,0]">Derivatives and the Shape of a Function (Review)</Font></Text-field>
<Text-field style="Heading 2" layout="Heading 2">What does a function's <Font bold="true" style="Text" size="14" foreground="[255,0,255]">first</Font> derivative reveal about its shape?</Text-field>
The first derivative of a function can be interpreted as the slopes of the tangent lines to the function.
Ni4tJStBWEVTTEFCRUxTRzYkUSJ4NiJRInlGJy0lJ0NVUlZFU0c2JTdqbjckJCEiJCIiISQhMzkrKysrKysmUSMhIzs3JCQhM05MJGUqWyNmIkhIISM8JCEzJTRuQDZbYCIzQEYzNyQkITNxbW0ielw9JGVHRjckITNbJj48VlJtLCg9RjM3JCQhM0VdKD0jUi5vJ3ojRjckITNjY2gjcCVwKT1wIkYzNyQkITNQTDNfIT1VXXQjRjckITMjXCw+Wm03IVE6RjM3JCQhMydvbVQmb11TJ2YjRjckITNhXGRmdUQxcTdGMzckJCEzUW07enoqW29YI0Y3JCEzO1FXPEhUOSI0IkYzNyQkITNATDN4d2gmekojRjckITNAdC5zJypvXkopKkY3NyQkITM3K0QiR1pxTkQjRjckITNBZD8qZlhKc14qRjc3JCQhMy1uVCYpb1o9Kj0jRjckITNrQExSIVIxIylIKkY3NyQkITN2TDN4LHJeQUBGNyQhM29eSiwwd3JiIipGNzckJCEzLyt2b00lXGUwI0Y3JCEzUV9FW2A+YyQzKkY3NyQkITMhbzthOCVRJnoiPkY3JCEzOzInXEphdmo0KkY3NyQkITMtK3YkNFsrMHkiRjckITNZLzU5JUdNXkIqRjc3JCQhM1VMTGUvRzZSO0Y3JCEzPmRveHNjNzUlKkY3NyQkITNybTtIaSV5WF4iRjckITMjUjZUUSpSZEQmKkY3NyQkITMhKioqKlwoKUcjUXU4RjckITMtJ2VucjQhXGAmKkY3NyQkITM1KytEYy9oTDdGNyQhM2diZkw7MnREJSpGNzckJCEzKSoqKipcN3JdejQiRjckITNLZ1BLQnV6QSIqRjc3JCQhM3FwO2FqbWVaKCohIz0kITNDdCxTYyplKXknKUY3NyQkITNfTUwkZTQ5RkcpRlxyJCEzb2wkeXc+KmVMekY3NyQkITN6TExMJClbeFRxRlxyJCEzZyRvZmpSQiM+ckY3NyQkITM3L10oPWRuIylmJkZcciQhMyFRPyRRIXAkPnNmRjc3JCQhM3BPTEwzIT4wSyVGXHIkITMzK3FgRXpnJXolRjc3JCQhMyQ+K3Y9S0UnPUhGXHIkITMpPVopeltvNWBMRjc3JCQhM3MpKlxpbEhwJGUiRlxyJCEzI29WJUg/ZSRcJz1GNzckJCEzTF1MJDNfKyQzPiEjPiQhM21XPVBPUzgnRyNGXHI3JCQiM29rO0gySEQpMyJGXHIkIjMhSFMmKSoqZXhVSiJGNzckJCIzX0lMM3htInpZI0ZcciQiM1NHeCQqWyl5OilIRjc3JCQiM01KJGVrZSoqNCFSRlxyJCIzdVs5MCUzKjNyWUY3NyQkIjNLKSpcKD1aLSZbXkZcciQiM1VyM3FvJD0hcGdGNzckJCIzK0pMZWsoUmVcJ0ZcciQiM3VgPFY0I2VZWShGNzckJCIzZycqKioqXC1yeCl5RlxyJCIzQEpvdktGNlYoKUY3NyQkIjNlJyoqXGk/LyZcIypGXHIkIjNZLW1sUUc6KHoqRjc3JCQiM1EqXDd5NTBuMCJGNyQiM1UkPmE3dU8tMSJGMzckJCIzPyoqXFBDaSpIPyJGNyQiM1QkKlJVLWozQTZGMzckJCIzcUszeGgyc283RjckIjM9YSZmPXY4KVI2RjM3JCQiM0BtbTsqSFhXTCJGNyQiMz8kUkhIJUczXjZGMzckJCIzOEwkZTlGP1lTIkY3JCIzdUVfc25jKGU6IkYzNyQkIjMvKyt2Vl96dTlGNyQiM0d5aScqUmQ4YDZGMzckJCIzYTt6cCk+JVFROkY3JCIzeiV6c15JYFQ5IkYzNyQkIjMvTGVrYEooPmciRjckIjNfJXlcOHRbIUg2RjM3JCQiM0IrK0QsQSxUPEY3JCIzKSkpKXpDIjMkSHY1RjM3JCQiM1tsInolNHIkPSg9RjckIjMrV1s8PCpHLisiRjM3JCQiMzsrRDFNb2UzP0Y3JCIzI1w2ZWJXMHcqKilGNzckJCIzc2xtVCZvJUdVQEY3JCIzI0g6aTJEJlxQeUY3NyQkIjNFKlw3YCVSRCNHI0Y3JCIzQ0U8T20nPW5cJ0Y3NyQkIjNtTExMeTQxPENGNyQiM2FENCZcS2h4OiZGNzckJCIzbUskMy1rP1xiI0Y3JCIzcjNXdCcpb29MUUY3NyQkIjNXbSJ6V3ZRO3AjRjckIjNHdHA9KnkncHdFRjc3JCQiM0kkZSpbR09YYUZGNyQiMyVHUi8lb1hOS0FGNzckJCIzOysrXS0mb3MiR0Y3JCIzbSRveVsqPTZpPUY3NyQkIjM5TDN4TzlFKilHRjckIjMlZScqZXRvayNbOkY3NyQkIjM3bTsvclZEaEhGNyQiMz8uJ29xQGdiUCJGNzckJCIzJ0hlay4vXU0qSEY3JCIzdW9GIlFLWjJOIkY3NyQkIjNOKlwobzRka0RJRjckIjNhP3lmOCE+PE8iRjc3JCQiM3c6Lyx6OCV5MCRGNyQiM3I5LGJVZyc0VCJGNzckJCIzZ0tMTFtxLiE0JEY3JCIzQnVQVFUyMCw6Rjc3JCQiMzs7SGRYO3BlSkY3JCIza25UbHZhdlQ9Rjc3JCQiM3IqXDdHQ1l0QSRGNyQiM3hmKSl6InAucFMjRjc3JCQiMyMqKlwoPWknbyhlTEY3JCIzKVEjRydRJjMhKT1VRjc3JCQiMysrKysrKysrTkY3JCIzQ3VtbW07eld1RjctJSZDT0xPUkc2JiUkUkdCRyRGMCEiIkZmX2xGZl9sLSUqVEhJQ0tORVNTRzYjIiIkLUYqNiU3UzckRi4kITM7TExMTExMeTtGMzckRjskITMkKSoqKipcSzJtQDtGMzckRkUkITNvbTthMC1OczpGMzckRkokITMyKyt2Z2Aqb14iRjM3JEZPJCEzKSkqKipcXyNIMmg5RjM3JEZUJCEzaG07Ly9lXjA5RjM3JEZobiQhMzkrXSgzQzJTTiJGMzckRmJvJCEzTEwkM3M1dDFJIkYzNyRGZ28kITM5K10oKXBbXlg3RjM3JEZccCQhM01MJDNkX0wwPiJGMzckRmFwJCEzeW1tO2IleVI4IkYzNyRGZnAkITM1KytEPVo7JTMiRjM3JEZbcSQhM1BMTCQpW2kzRzVGMzckRmBxJCEzaExMTGVeeDwoKkY3NyRGZXEkITNHS0xMeWg4diIqRjc3JEZqcSQhMzMsK3YpKnpPI28pRjc3JEZgciQhMy1ubW1yKj1rNClGNzckRmVyJCEzdG1tbSdHVitnKEY3NyRGanIkITMnW0wkM2kua0FxRjc3JEZfcyQhMyp5bW1tJDRhNmxGNzckRmRzJCEzKVJMJDNpUXldZkY3NyRGaXMkITNxS0xlPjAib1QmRjc3JEZedCQhM0FubTthYG1mW0Y3NyRGZHQkITNNbm1UcUAuW1ZGNzckRml0JCEzKywrXWltOyd6JEY3NyRGXnUkITNvKyt2KVxMSEEkRjc3JEZjdSQhMypRTCRlV0IkUnMjRjc3JEZodSQhMyEzKyt2VSgqXD0jRjc3JEZddiQhM2RNTExCXEFHO0Y3NyRGYnYkITNlTUwkM2xKTjMiRjc3JEZndiQhMy9kTCQzLUheYyZGXHI3JEZcdyQiMytmam07azpsR0ZgdDckRmZ3JCIzRDtMTEwneVdhJkZccjckRmB4JCIzJnBtbTtrWmU2IkY3NyRGangkIjMkKikqKlw3R2ZYaSJGNzckRl95JCIzb25tbXJhciE9I0Y3NyRGZHkkIjNzR0xlL14sL0ZGNzckRml5JCIzVW5tIkgrOTVEJEY3NyRGXnokIjNvSExMM2EhZXkkRjc3JEZjeiQiMyFRbTt6VyNvWFZGNzckRmh6JCIzVywrKyFlNVwpW0Y3NyRGXVtsJCIzUSgqKipcRiNcalYmRjc3JEZiW2wkIjNnS0xlJW9ASylmRjc3JEZcXGwkIjNXbm1tdzF1JlsnRjc3JEZmXGwkIjNDSkwkMzolb2hxRjc3JEZqXWwkIjM7KCoqKioqZlsib2QoRjc3JEZkXmwkIjNqbG0iempeZzcpRjc3JEZpXmwkIjNZbW1UOjh1XicpRjc3JEZeX2wkIjN5bW1tbW1tOyMqRjctRmNfbDYmRmVfbEZmX2xGZl9sJCIjNUZnX2wtRmlfbDYjIiIiLUYqNiU3UzckRi4kITNtKioqKioqKipmRE9CRjc3JEY7JCEzSSoqKnpvOVsjej1GNzckRkUkITNpKyEpW2QhMztbIkY3NyRGSiQhM0UrISkzKj0/Vy4iRjc3JEZPJCEzVSopKmZAcCFvVWVGXHI3JEZUJCEzVSopKj56VmFETyJGXHI3JEZobiQiM0ckKipSZTQnNCJ6I0ZccjckRmJvJCIzIVsrP1pqZz40KEZccjckRmdvJCIzISkqKnpLKjMjKlI6IkY3NyRGXHAkIjNZKyEpb1s7TyhmIkY3NyRGYXAkIjNXK2dgUDxVYD9GNzckRmZwJCIzSSs/LjcoPl5YI0Y3NyRGW3EkIjNGKyEzJSpbT3QhSEY3NyRGYHEkIjM/KytLNyxUaExGNzckRmVxJCIzVSs/eiY9JSoqKXokRjc3JEZqcSQiMzUqKnohZVdpaj4lRjc3JEZgciQiMzMrIVs3dXIpb1lGNzckRmVyJCIzRys/aiQ0XCJwXUY3NyRGanIkIjN1KSpmLDdvd01iRjc3JEZfcyQiM1sqKj5uKVE8cCVmRjc3JEZkcyQiM1MqKmZoJCo9NipSJ0Y3NyRGaXMkIjNlKyEzcSp6cUhvRjc3JEZedCQiMzcrK1NlKSopKnlzRjc3JEZkdCQiMy0rZ3hkM2QicChGNzckRml0JCIzJykpKipmTD8mZk8iKUY3NyRGXnUkIjNDKip6Z0UvJikpZilGNzckRmN1JCIzeSoqektkXEMsISpGNzckRmh1JCIzZSkqUll1PyVlVipGNzckRl12JCIzdykqUiM9VUJbKSkqRjc3JEZidiQiMyoqKnp3d1MxQy4iRjM3JEZndiQiMycpKipmZCo+MFwyIkYzNyRGXHckIjN1KlJNQCdHNEE2RjM3JEZmdyQiMy0rIypwdklcazZGMzckRmB4JCIzKSoqKlIjUU5rKDQ3RjM3JEZqeCQiMykpKioqUi8nb3ldN0YzNyRGX3kkIjM1K19qJkhOY0giRjM3JEZkeSQiM3UqZkwheVQkeUwiRjM3JEZpeSQiMzUrXz5wVCU+USJGMzckRl56JCIzeSoqejdbKHBdVSJGMzckRmN6JCIzIyoqKioqZksjPS1aIkYzNyRGaHokIjM+Kzc8KmUsUF4iRjM3JEZdW2wkIjNtKmYwPGdwImU6RjM3JEZiW2wkIjMkKip6V21ScEFnIkYzNyRGXFxsJCIzRCtrO0dEelU7RjM3JEZmXGwkIjMnKio+Qio0bUIqbyJGMzckRmpdbCQiMyYqKlI1LnZ3MnQiRjM3JEZkXmwkIjMlKipmIjMvczF2PEYzNyRGaV5sJCIzOCtfbj4pZXUiPUYzNyRGXl9sJCIzOSsrKytXLGo9RjMtRmNfbDYmRmVfbEZkaWxGZl9sRmZfbEZmaWwtRio2JTdTNyRGLiQiM2MrKytuKHAxKWVGMzckRjskIjN1Jio9SSMqUk9TZEYzNyRGRSQiMydvKHolem8lRz1jRjM3JEZKJCIzWUZoS1VQKjRbJkYzNyRGTyQiMzYhKnk+VkZ6VWBGMzckRlQkIjNAKlElSCplW18/JkYzNyRGaG4kIjNHJGZbPGJGeDImRjM3JEZibyQiM28lb3dPIXBvWFxGMzckRmdvJCIzPT1ZYnctODRbRjM3JEZccCQiM1koZm4jKWU2SW4lRjM3JEZhcCQiM3dIM0QneScqSGAlRjM3JEZmcCQiM1s5R1VzO240V0YzNyRGW3EkIjNZUGlzLm8kM0YlRjM3JEZgcSQiMypHIik+ZCc9VkpURjM3JEZlcSQiM21pUCVvUCozKCpSRjM3JEZqcSQiM1lvUXFFTjR2UUYzNyRGYHIkIjNuemk+aCdHK3QkRjM3JEZlciQiMypwaEA+cFJyZyRGMzckRmpyJCIzRzVfUDExPmtNRjM3JEZfcyQiM0BVaShRV2N3TCRGMzckRmRzJCIzaWYqR0lURykpPiRGMzckRmlzJCIzR3lHcChISm0xJEYzNyRGXnQkIjMqM3dGaVoocEdIRjM3JEZkdCQiMylRIlElKXA2Li1HRjM3JEZpdCQiMy06XlFZV1NsRUYzNyRGXnUkIjMlemhfKnl3W0JERjM3JEZjdSQiM3MhcDdkclsqKlIjRjM3JEZodSQiM1l4SSY0REJsRSNGMzckRl12JCIzZ3ZfOyFwIm9HQEYzNyRGYnYkIjM1cCNmXGhJUSo+RjM3JEZndiQiMz1nVnlsX05qPUYzNyRGXHckIjM/I29qZmolWz08RjM3JEZmdyQiMzlVIylvSj5KKWUiRjM3JEZgeCQiM1k3bzEmeUMkXDlGMzckRmp4JCIzLm9nbnM8UUI4RjM3JEZfeSQiM09QVEEleiNwJj0iRjM3JEZkeSQiMzV4USZlPlFoMCJGMzckRml5JCIzKSpvQyc0NmpyPypGNzckRl56JCIzXSpIKHllbTskKXlGNzckRmN6JCIzSV5bJ1wybHFcJ0Y3NyRGaHokIjNBSEdtMlgzaV5GNzckRl1bbCQiMyVIITQzaVMob3okRjc3JEZiW2wkIjNgaCNvI1sjb0hXI0Y3NyRGXFxsJCIzQ1lGZjslcCkpPiJGNzckRmZcbCQhM0tUXikpNEMzcUFGXHI3JEZqXWwkITMiKWUsJWZASUJdIkY3NyRGZF5sJCEzcy96JXpWKjNpR0Y3NyRGaV5sJCEzJVJmd1peX047JUY3NyRGXl9sJCEzKSoqKioqKipIQjppYkY3LUZjX2w2JkZlX2xGZl9sRmRpbEZmX2xGZmlsLSUlVEVYVEc2JjckJCEjP0ZnX2wkISNnRmdfbFElZih4KUYnJSpBTElHTkxFRlRHLSUlRk9OVEc2JSUmVElNRVNHJSZST01BTkciIzktRmpcbjYnNyQkISM6RmdfbCQhJD8iRmdfbFEyc2xvcGV+aXN+cG9zaXRpdmVGJyUrQUxJR05SSUdIVEctRmRdbjYlRmZdbkZnXW4iIzdGYmlsLUZqXG42JzckRmRpbCQiMi0rKysrKys/IkZdXm5GYF5uRmJdbkZiXm5GX2NtLUZqXG42JzckJCIjP0ZnX2xGaF5uUTJzbG9wZX5pc35uZWdhdGl2ZUYnRmFebkZiXm5GZ1xuLSUqR1JJRFNUWUxFRzYjJSxSRUNUQU5HVUxBUkctRmNfbDYjJSVOT05FRy0lJVZJRVdHNiQ7JCEjSUZnX2wkIiNORmdfbDskISQrI0ZnX2wkRl5fbkYw
When a tangent line has positive slope, the function is ________________. (You fill in the blanks throughout.)
So when the first derivative is positive, the function must be ________________.
When a tangent line has negative slope, the function is ________________.
So when the first derivative is negative, the function must be ________________.
What happens when the first derivative is zero?
6+-%+AXESLABELSG6'Q"x6"Q"yF'-%%FONTG6$%*HELVETICAG"#5%+HORIZONTALGF.-%'CURVESG6%7jn7$$!"$""!$!39++++++&Q#!#;7$$!3NL$e*[#f"HH!#<$!3%4n@6[`"3@F97$$!3qmm"z\=$eGF=$!3[&><VRm,(=F97$$!3E](=#R.o'z#F=$!3cch#p%p)=p"F97$$!3PL3_!=U]t#F=$!3#\,>Zm7!Q:F97$$!3'omT&o]S'f#F=$!3a\dfuD1q7F97$$!3Qm;zz*[oX#F=$!3;QW<HT9"4"F97$$!3@L3xwh&zJ#F=$!3@t.s'*o^J)*F=7$$!37+D"GZqND#F=$!3Ad?*fXJs^*F=7$$!3-nT&)oZ=*=#F=$!3k@LR!R1#)H*F=7$$!3vL3x,r^A@F=$!3o^J,0wrb"*F=7$$!3/+voM%\e0#F=$!3Q_E[`>c$3*F=7$$!3!o;a8%Q&z">F=$!3;2'\Javj4*F=7$$!3-+v$4[+0y"F=$!3Y/59%GM^B*F=7$$!3ULLe/G6R;F=$!3>doxsc75%*F=7$$!3rm;Hi%yX^"F=$!3#R6TQ*RdD&*F=7$$!3!****\()G#Qu8F=$!3-'enr4!\`&*F=7$$!35++Dc/hL7F=$!3gbfL;2tD%*F=7$$!3)****\7r]z4"F=$!3KgPKBuzA"*F=7$$!3qp;ajmeZ(*!#=$!3Ct,Sc*e)y')F=7$$!3_ML$e49FG)Fbr$!3ol$yw>*eLzF=7$$!3zLLL$)[xTqFbr$!3g$ofjRB#>rF=7$$!37/](=dn#)f&Fbr$!3!Q?$Q!p$>sfF=7$$!3pOLL3!>0K%Fbr$!33+q`Ezg%z%F=7$$!3$>+v=KE'=HFbr$!3)=Z)z[o5`LF=7$$!3s)*\ilHp$e"Fbr$!3#oV%H?e$\'=F=7$$!3L]L$3_+$3>!#>$!3mW=POS8'G#Fbr7$$"3ok;H2HD)3"Fbr$"3!HS&)**exUJ"F=7$$"3_IL3xm"zY#Fbr$"3SGx$*[)y:)HF=7$$"3MJ$eke**4!RFbr$"3u[90%3*3rYF=7$$"3K)*\(=Z-&[^Fbr$"3Ur3qo$=!pgF=7$$"3+JLek(Re\'Fbr$"3u`<V4#eYY(F=7$$"3g'****\-rx)yFbr$"3@JovKF6V()F=7$$"3e'**\i?/&\#*Fbr$"3Y-mlQG:(z*F=7$$"3Q*\7y50n0"F=$"3U$>a7uO-1"F97$$"3?**\PCi*H?"F=$"3T$*RU-j3A6F97$$"3qK3xh2so7F=$"3=a&f=v8)R6F97$$"3@mm;*HXWL"F=$"3?$RHH%G3^6F97$$"38L$e9F?YS"F=$"3uE_snc(e:"F97$$"3/++vV_zu9F=$"3Gyi'*Rd8`6F97$$"3a;zp)>%QQ:F=$"3z%zs^I`T9"F97$$"3/Lek`J(>g"F=$"3_%y\8t[!H6F97$$"3B++D,A,T<F=$"3))))zC"3$Hv5F97$$"3[l"z%4r$=(=F=$"3+W[<<*G.+"F97$$"3;+D1Moe3?F=$"3#\6ebW0w**)F=7$$"3slmT&o%GU@F=$"3#H:i2D&\PyF=7$$"3E*\7`%RD#G#F=$"3CE<Om'=n\'F=7$$"3mLLLy41<CF=$"3aD4&\Khx:&F=7$$"3mK$3-k?\b#F=$"3r3Wt')ooLQF=7$$"3Wm"zWvQ;p#F=$"3Gtp=*y'pwEF=7$$"3I$e*[GOXaFF=$"3%GR/%oXNKAF=7$$"3;++]-&os"GF=$"3m$oy[*=6i=F=7$$"39L3xO9E*)GF=$"3%e'*etok#[:F=7$$"37m;/rVDhHF=$"3?.'oq@gbP"F=7$$"3'Hek./]M*HF=$"3uoF"QKZ2N"F=7$$"3N*\(o4dkDIF=$"3a?yf8!><O"F=7$$"3w:/,z8%y0$F=$"3r9,bUg'4T"F=7$$"3gKLL[q.!4$F=$"3BuPTU20,:F=7$$"3;;HdX;peJF=$"3knTlvavT=F=7$$"3r*\7GCYtA$F=$"3xf))z"p.pS#F=7$$"3#**\(=i'o(eLF=$"3)Q#G'Q&3!)=UF=7$$"3++++++++NF=$"3Cummm;zWuF=-%&COLORG6&%$RGBG$F6!""F\`lF\`l-%*THICKNESSG6#""$-F06%7S7$F4$!3Wmmmmmmm!*F=7$$!3qmm;%)R[pHF=Ff`l7$$!3HL$e>;KH%HF=Ff`l7$$!3"om;4'=28HF=Ff`l7$$!3emmTEO,$)GF=Ff`l7$$!3cL$eMD)4`GF=Ff`l7$$!3pm;HtGODGF=Ff`l7$$!37+]i$\Wmz#F=Ff`l7$$!3#om"H/R%pw#F=Ff`l7$$!3'***\7l&Qtt#F=Ff`l7$$!3MLL$[$e)oq#F=Ff`l7$$!3smmT`I1!o#F=Ff`l7$$!3?++]ap')\EF=Ff`l7$$!3******\noa>EF=Ff`l7$$!31++]XyK!f#F=Ff`l7$$!3cm;HuTzjDF=Ff`l7$$!3RLL$G2VA`#F=Ff`l7$$!3OLLL^^^0DF=Ff`l7$$!3M+]iCUUuCF=Ff`l7$$!3WLLL'[.pW#F=Ff`l7$$!3%)**\iu)3nT#F=Ff`l7$$!3;+](QYczQ#F=Ff`l7$$!3iLLeRj&zN#F=Ff`l7$$!3XL$e/'oSIBF=Ff`l7$$!3fmmTD5p+BF=Ff`l7$$!3mm;HCY#)pAF=Ff`l7$$!39+]PJ`&HC#F=Ff`l7$$!3hmm"*ed$R@#F=Ff`l7$$!3O+++,d&R=#F=Ff`l7$$!3G++Djgia@F=Ff`l7$$!32+]iI"[i7#F=Ff`l7$$!3?++vu#RZ4#F=Ff`l7$$!3yLLLmrUm?F=Ff`l7$$!3$)****\Zz>O?F=Ff`l7$$!3tm;H#y0)3?F=Ff`l7$$!33++]5*e)y>F=Ff`l7$$!3gL$ezB"o]>F=Ff`l7$$!3/+]7^uA@>F=Ff`l7$$!3ULL$3*4V#*=F=Ff`l7$$!3?+]ilPGi=F=Ff`l7$$!3hmmm/%[K$=F=Ff`l7$$!3#om;WbbN!=F=Ff`l7$$!3]L$efd3Tx"F=Ff`l7$$!3/+++h)\qu"F=Ff`l7$$!3KLL3?v.;<F=Ff`l7$$!3ymmm7(*H)o"F=Ff`l7$$!31+]iCase;F=Ff`l7$$!3:+]Pd!>/j"F=Ff`l7$$!33+++++++;F=Ff`l-Fi_l6&F[`l$F-F]`lF\`lF\`l-F_`l6#"""-F06%7S7$$!"#F6$!3O6">dEh%f&*F=7$$!3ymmm"p0k&>F=Fdjl7$$!3FLL3<XZ=>F=Fdjl7$$!3cmm;Wp"e(=F=Fdjl7$$!3hmm;4m(G$=F=Fdjl7$$!3QLL3i.9!z"F=Fdjl7$$!3emmT!R=0v"F=Fdjl7$$!3)****\P8#\4<F=Fdjl7$$!3!om;/siqm"F=Fdjl7$$!3%****\(y$pZi"F=Fdjl7$$!3ILLLyaE"e"F=Fdjl7$$!3mmm;>s%Ha"F=Fdjl7$$!3/+++N*4)*\"F=Fdjl7$$!3-+++Db\c9F=Fdjl7$$!3*)*****\1aZT"F=Fdjl7$$!3ommT?)[oP"F=Fdjl7$$!3ZLLL=exJ8F=Fdjl7$$!3SLLLtIf$H"F=Fdjl7$$!3;++vju<\7F=Fdjl7$$!3aLLLB@')47F=Fdjl7$$!3'****\P'psm6F=Fdjl7$$!35++D"4_c7"F=Fdjl7$$!3ULL$3x%z#3"F=Fdjl7$$!3MLL3s$QM/"F=Fdjl7$$!3pmm;zr)4+"F=Fdjl7$$!3Iom;/K#*o&*FbrFdjl7$$!3-,+]ih2&=*FbrFdjl7$$!3snmmT3^q()FbrFdjl7$$!3q++++VAU$)FbrFdjl7$$!33-++v%HK#zFbrFdjl7$$!3d,+]P/$y^(FbrFdjl7$$!3y,++DRqnqFbrFdjl7$$!3uMLLL_CjmFbrFdjl7$$!3R+++]#*RJiFbrFdjl7$$!3enm;/E3SeFbrFdjl7$$!3M+++],F7aFbrFdjl7$$!3VNL$3(>t4]FbrFdjl7$$!3?,+](ej*)e%FbrFdjl7$$!3=MLL$e&exTFbrFdjl7$$!3#4++v$4"pu$FbrFdjl7$$!3;mmmm+7KLFbrFdjl7$$!3Bnmm"\Oz!HFbrFdjl7$$!3mLL$3Pls[#FbrFdjl7$$!3`++++Br+@FbrFdjl7$$!3]LLLe)ywl"FbrFdjl7$$!3UnmmmWUh7FbrFdjl7$$!3E&****\PY$*Q)FftFdjl7$$!3i&****\izbM%FftFdjl7$$F6F6Fdjl-Fi_l6&F[`lF\`lF\`lFjilF[jl-F06%7S7$Fdcm$"396>dEh%f:"F97$$"3+LLLeR+HwFftF[dm7$$"3'omT5&fpE9FbrF[dm7$$"3MLL3xM?t@FbrF[dm7$$"3oLLeR$fY#HFbrF[dm7$$"3'pmTNmVDn$FbrF[dm7$$"3OL$3x;GfO%FbrF[dm7$$"3U+]Pfw)Q3&FbrF[dm7$$"3;M$3FR-k#eFbrF[dm7$$"3)***\(=(e`mlFbrF[dm7$$"3nnm;HT&yK(FbrF[dm7$$"3'RL$ekOU)*zFbrF[dm7$$"3a,+]PhK`()FbrF[dm7$$"3L++]7$G8^*FbrF[dm7$$"33++D'Q!=C5F=F[dm7$$"3OL3FkX^!4"F=F[dm7$$"3wmm"zJ#Rp6F=F[dm7$$"3$omm;77iB"F=F[dm7$$"30+vVQ%RRJ"F=F[dm7$$"3kmm;%GTFQ"F=F[dm7$$"3=+vV8yAe9F=F[dm7$$"3F+DJS)3,`"F=F[dm7$$"3&omT5:4^g"F=F[dm7$$"3#o;a)[G)Rn"F=F[dm7$$"3IL$ekVs#[<F=F[dm7$$"3QL3FR%Qa#=F=F[dm7$$"33+Dcr;h#*=F=F[dm7$$"3[L$3Fgg^'>F=F[dm7$$"3******\Z26S?F=F[dm7$$"3>+](=%[V8@F=F[dm7$$"3G+vVt'zV=#F=F[dm7$$"3#***\78=:jAF=F[dm7$$"3Umm;%3KRL#F=F[dm7$$"3V++DJ^]4CF=F[dm7$$"3=L3FWb)zZ#F=F[dm7$$"3]++vBF&Gb#F=F[dm7$$"3emT50pHBEF=F[dm7$$"35+v=s8$pp#F=F[dm7$$"3umm"H_A*oFF=F[dm7$$"3$)*\Pfe!HWGF=F[dm7$$"3#RLL$))*yo"HF=F[dm7$$"3_L$eR666*HF=F[dm7$$"3;nT5g&GZ1$F=F[dm7$$"3Y++]Z`PKJF=F[dm7$$"3"pm"z*>1*4KF=F[dm7$$"3[LLL=2DzKF=F[dm7$$"33+vVQk=`LF=F[dm7$$"3I+DccB&RU$F=F[dm7$Fd_lF[dm-Fi_l6&F[`lF\`lFjilF\`lF[jl-F06%7S7$$""#F6$"33++++++]8F=7$$"3.++DJdpK?F=Fc]n7$$"3#)*\(=7T9h?F=Fc]n7$$"3=+](=HPJ4#F=Fc]n7$$"3$***\7VDMD@F=Fc]n7$$"39+vVGZRd@F=Fc]n7$$"3%)*\(=276(=#F=Fc]n7$$"38+vo**3)y@#F=Fc]n7$$"3A+vofHq\AF=Fc]n7$$"3#)*\Pf'HU"G#F=Fc]n7$$"3'****\7*309BF=Fc]n7$$"3$)**\i&e*yUBF=Fc]n7$$"3'****\([D9vBF=Fc]n7$$"30++Dc$GwS#F=Fc]n7$$"3>++D^W$*QCF=Fc]n7$$"3%)*\(o%QjtY#F=Fc]n7$$"3,++DO"o6]#F=Fc]n7$$"3y*****\>0)HDF=Fc]n7$$"3w*\(=-p6jDF=Fc]n7$$"3'*****\2Mg#f#F=Fc]n7$$"3#**\(=xZ&\i#F=Fc]n7$$"3#**\i:$4wbEF=Fc]n7$$"3#)**\(=#R!zo#F=Fc]n7$$"3;+v$4A@ur#F=Fc]n7$$"3A+]i:'f#\FF=Fc]n7$$"3)**\(of2L#y#F=Fc]n7$$"3w*\7yG>6"GF=Fc]n7$$"3D+](oo6A%GF=Fc]n7$$"31++]xJLuGF=Fc]n7$$"3'***\P*ydd!HF=Fc]n7$$"3***\(=<F;OHF=Fc]n7$$"35+]i0A#*pHF=Fc]n7$$"3*)****\2mD+IF=Fc]n7$$"3!)***\i0XE.$F=Fc]n7$$"3%**\(o/Q*>1$F=Fc]n7$$"33++vQ(zS4$F=Fc]n7$$"3!**\(=-,FCJF=Fc]n7$$"3C+v$4tFe:$F=Fc]n7$$"3q***\73"o'=$F=Fc]n7$$"3$**\(oz;)*=KF=Fc]n7$$"3))*****\*44]KF=Fc]n7$$"3-+]7jZ!>G$F=Fc]n7$$"34+v=(4bMJ$F=Fc]n7$$"32++]xlWULF=Fc]n7$$"3/+]i&3ucP$F=Fc]n7$$"3++++lJR0MF=Fc]n7$$"3.+v=-*zqV$F=Fc]n7$$"3E+D"G:3uY$F=Fc]n7$Fd_lFc]n-Fi_l6&F[`lFjilF\`lFjilF[jl-%*GRIDSTYLEG6#%,RECTANGULARG-Fi_l6#%%NONEG-%%VIEWG6$;$!#IF]`l$"#NF]`l;$!$+#F]`l$"#8F6
What can you say about the points at which the first derivative is zero?
<Text-field style="Heading 2" layout="Heading 2">What does a function's <Font bold="true" style="Text" size="14" foreground="[255,0,255]">second</Font> derivative reveal about its shape?</Text-field>
In Lab 4 you answered many questions about when the graph of a function lies above or below its tangent lines. Fill in the blanks below to solidify your understanding of this concept!
Case 1: The function is increasing and the graph of the function lies above its tangent lines.
The graph shown is that of f, together with several of its tangent lines. Each tangent line is graphed for a "run" of 1, i.e. the change in x from start to stop of the tangent line is 1. Estimate the slope of each tangent line.
6(-%+AXESLABELSG6'Q"x6"Q!F'-%%FONTG6$%*HELVETICAG"#5%+HORIZONTALGF.-%%TEXTG6&7$$!#5!""$!")F5Q)y~=~f(x)F'%+ALIGNRIGHTG-F*6%%&TIMESG%'ITALICG"#7-%'CURVESG6)7S7$$F5""!$!3M<zG#G)4T!)!#=7$$!3Umm;/'*4P#*FH$!3)3^)z$zG-K)FH7$$!3UL$e*[SIt&)FH$!3Wut'\jcra)FH7$$!3%pm;H_'zEyFH$!3mJ5D)o4Ty)FH7$$!3)om;/mS`2(FH$!38hs"G2*f-!*FH7$$!3]K$ekLcuK'FH$!3W!>8)z!)f*>*FH7$$!3>n;HK=2McFH$!3))*z!32Oij$*FH7$$!3e**\iSB6;\FH$!3qV%Qv@NU^*FH7$$!3%em"H2wftTFH$!3)*)f"*el!4\'*FH7$$!3,+]7GTYLMFH$!3q"HRd4h?w*FH7$$!3KKL$3(e9sEFH$!3[@G[&eac&)*FH7$$!3-mmTNjd,?FH$!34h%3)>]#*=**FH7$$!3Y)***\iQnY7FH$!3gb"o$Q>_o**FH7$$!3u'****\(or')[!#>$!3%f1q,Hh^***FH7$$"3W2++D'Q!=CFbq$!3CJFb">:))***FH7$$"3aPL3FkX^!*Fbq$!3yx%pXL-M)**FH7$$"3cnm;zJ#Rp"FH$!37g2p<1">%**FH7$$"3Iomm;77iBFH$!3%piS[BYr))*FH7$$"3^+]P%Q%RRJFH$!3)QuZDrV4!)*FH7$$"3SmmmTGTFQFH$!3r"f@"zJh/(*FH7$$"3'=+vV8yAe%FH$!3!=>V*f^^x&*FH7$$"3t-]7.%)3,`FH$!3Hm0+tz#fV*FH7$$"3[omT5:4^gFH$!3Wy)H3:TrE*FH7$$"3;o;a)[G)RnFH$!3cWP5.r_$4*FH7$$"3-LLekVs#[(FH$!3!>!\WMhn')))FH7$$"3!QL3FR%Qa#)FH$!3e*)>;q-y]')FH7$$"3)4+Dcr;h#*)FH$!3?$4&e-wTG%)FH7$$"3#[L$3Fgg^'*FH$!33(GWEHi4<)FH7$$"3******\Z26S5!#<$!3Sp=\**3p')yFH7$$"3>+](=%[V86F^v$!3)\#)ou%)47f(FH7$$"3G+vVt'zV="F^v$!3)4./\(zc*G(FH7$$"3#***\78=:j7F^v$!3t>Y<!\bs$pFH7$$"3Umm;%3KRL"F^v$!3L,OG%)Hy0mFH7$$"3V++DJ^]49F^v$!3_AQ^&fzqB'FH7$$"3=L3FWb)zZ"F^v$!3sY4Eu+\!*eFH7$$"3]++vBF&Gb"F^v$!3%QEh]!=z)\&FH7$$"3emT50pHB;F^v$!3]JS%y!Q")=^FH7$$"35+v=s8$pp"F^v$!3Pefs#*pj5ZFH7$$"3umm"H_A*o<F^v$!35!Q#fzsb,VFH7$$"3$)*\Pfe!HW=F^v$!31-#>m0CO'QFH7$$"3#RLL$))*yo">F^v$!3Yw=e!QBMV$FH7$$"3_L$eR666*>F^v$!3kWIl^n!f)HFH7$$"3;nT5g&GZ1#F^v$!3?&)>Nv%3b`#FH7$$"3Y++]Z`PK@F^v$!3>kai:kq;@FH7$$"3"pm"z*>1*4AF^v$!37=qbM;$>j"FH7$$"3[LLL=2DzAF^v$!3U/e**z.%\>"FH7$$"33+vVQk=`BF^v$!3_wJu&*esksFbq7$$"3I+DccB&RU#F^v$!3?-V1M-olFFbq7$$"3++++++++DF^v$"3m-J"fWh^2#Fbq7S7$$!3++++++++]FHFD7$$!3MLLLe%G?y%FHFD7$$!3OmmT&esBf%FHFD7$$!3KLL$3s%3zVFHFD7$$!33LL$e/$QkTFHFD7$$!3!pm;/"=q]RFHFD7$$!3SLL3_>f_PFHFD7$$!3))***\(o1YZNFHFD7$$!3]LL3-OJNLFHFD7$$!3C++v$*o%Q7$FHFD7$$!3ammm"RFj!HFHFD7$$!3JLL$e4OZr#FHFD7$$!3=+++v'\!*\#FHFD7$$!33+++DwZ#G#FHFD7$$!3-+++D.xt?FHFD7$$!3OLL3-TC%)=FHFD7$$!3!omm;4z)e;FHFD7$$!3+nmmm`'zY"FHFD7$$!3E++v=t)eC"FHFD7$$!39nmm;1J\5FHFD7$$!3&y***\(=[jL)FbqFD7$$!3M****\iXg#G'FbqFD7$$!3WlmmT&Q(RTFbqFD7$$!3;nm;/'=><#FbqFD7$$!3vDMLLe*e$\!#@FD7$$"3[em;zRQb@FbqFD7$$"3'[***\(=>Y2%FbqFD7$$"3Qhmm"zXu9'FbqFD7$$"3]'******\y))G)FbqFD7$$"3'*)***\i_QQ5FHFD7$$"3@***\7y%3T7FHFD7$$"35****\P![hY"FHFD7$$"3kKLL$Qx$o;FHFD7$$"3!)*****\P+V)=FHFD7$$"3?mm"zpe*z?FHFD7$$"3%)*****\#\'QH#FHFD7$$"3GKLe9S8&\#FHFD7$$"3R***\i?=bq#FHFD7$$"3"HLL$3s?6HFHFD7$$"3a***\7`Wl7$FHFD7$$"3#pmmm'*RRL$FHFD7$$"3Qmm;a<.YNFHFD7$$"3=LLe9tOcPFHFD7$$"3u******\Qk\RFHFD7$$"3CLL$3dg6<%FHFD7$$"3ImmmmxGpVFHFD7$$"3A++D"oK0e%FHFD7$$"3A++v=5s#y%FHFD7$$"3++++++++]FHFD7S7$$FEFE$!3'QT7"\XQ\5F^v7$$"3emmm;arz@Fbq$!3OZ*e\tT]/"F^v7$$"3[LL$e9ui2%Fbq$!3E<\evIET5F^v7$$"3nmmm"z_"4iFbq$!3bt6#zd8q."F^v7$$"3[mmmT&phN)Fbq$!3pk%G="ftK5F^v7$$"3CLLe*=)H\5FH$!3u#*ftw&y%G5F^v7$$"3gmm"z/3uC"FH$!3pX%G@[JX-"F^v7$$"3%)***\7LRDX"FH$!3"G(pG%\W/-"F^v7$$"3]mm"zR'ok;FH$!3ED[hDx@;5F^v7$$"3w***\i5`h(=FH$!3q9MC7X+75F^v7$$"3WLLL3En$4#FH$!3dm6U/2n25F^v7$$"3qmm;/RE&G#FH$!3i*QKT[`Q+"F^v7$$"3")*****\K]4]#FH$!3_KR$>)>c&***FH7$$"3$******\PAvr#FH$!3!pca=n7C&**FH7$$"3)******\nHi#HFH$!39o.A;.$3"**FH7$$"3jmm"z*ev:JFH$!39aOk`&pI()*FH7$$"3?LLL347TLFH$!3U*ySYNo"G)*FH7$$"3,LLLLY.KNFH$!3u$R&Q\68!z*FH7$$"3w***\7o7Tv$FH$!3]iS7P[)eu*FH7$$"3'GLLLQ*o]RFH$!33&pBNN>nq*FH7$$"3A++D"=lj;%FH$!3qp)=1h[Pm*FH7$$"31++vV&R<P%FH$!3%f'zn,.$Gi*FH7$$"3WLL$e9Ege%FH$!3)>i5*Qj8!e*FH7$$"3GLLeR"3Gy%FH$!3LQuZ`*H4a*FH7$$"3cmm;/T1&*\FH$!3/`!*=q0k)\*FH7$$"3&em;zRQb@&FH$!3[qq;'y8ZX*FH7$$"3\***\(=>Y2aFH$!3GH_a"RvkT*FH7$$"39mm;zXu9cFH$!3A)eyx(o<v$*FH7$$"3l******\y))GeFH$!3Sn^*>Z6DL*FH7$$"3'*)***\i_QQgFH$!35P%*='pr2H*FH7$$"3@***\7y%3TiFH$!3k3"yoJ'Q]#*FH7$$"35****\P![hY'FH$!3]d:nQ_a0#*FH7$$"3kKLL$Qx$omFH$!3_[a^NNDl"*FH7$$"3!)*****\P+V)oFH$!3/iWIUNBA"*FH7$$"3?mm"zpe*zqFH$!3o1rUM5D$3*FH7$$"3%)*****\#\'QH(FH$!3qAvocGjS!*FH7$$"3GKLe9S8&\(FH$!3WHousC`+!*FH7$$"3R***\i?=bq(FH$!31z$Gr,;'e*)FH7$$"3"HLL$3s?6zFH$!3y+38?]j<*)FH7$$"3a***\7`Wl7)FH$!3epa>9<tu))FH7$$"3#pmmm'*RRL)FH$!3H!)3SJ2TL))FH7$$"3Qmm;a<.Y&)FH$!3mH;PeS:"z)FH7$$"3=LLe9tOc()FH$!3i%**H>HZ#\()FH7$$"3u******\Qk\*)FH$!31H&QeKR2r)FH7$$"3CLL$3dg6<*FH$!37kf2^[gm')FH7$$"3ImmmmxGp$*FH$!3!HV<2XIri)FH7$$"3A++D"oK0e*FH$!3QNFn1D/&e)FH7$$"3A++v=5s#y*FH$!3!fI@R(*eZa)FH7$$"""FE$!3%Qj3l")o9])FH7S7$Fhel$!3"H!Q'*R$*QL**FH7$$"35mmmT:(z@&FH$!3_r!R,A'*3&)*FH7$$"3jLLe9ui2aFH$!3'e)ym(R>"z(*FH7$$"3Anm;z_"4i&FH$!39?b*Q&))R)p*FH7$$"3$pmmT&phNeFH$!3Y99'>CVrh*FH7$$"35LLe*=)H\gFH$!3H&*pwBQFO&*FH7$$"3;nm"z/3uC'FH$!3#[n%4@vHh%*FH7$$"37++DJ$RDX'FH$!3;EWZ-Rm$Q*FH7$$"3'fm;zR'okmFH$!3wC8/.^P.$*FH7$$"3I++D1J:woFH$!3*4E13zVLA*FH7$$"3WLLL3En$4(FH$!3'*zP2\<-T"*FH7$$"3qmm;/RE&G(FH$!3C!*p!*\C^o!*FH7$$"3")*****\K]4](FH$!3U#)f#G:%)o)*)FH7$$"3$******\PAvr(FH$!3jwW6#o?\!*)FH7$$"3`+++v'Hi#zFH$!3tR@i!pLf#))FH7$$"3jmm"z*ev:")FH$!3W"3e_$f?a()FH7$$"3kKLL347T$)FH$!3O$=tkp9*o')FH7$$"3,LLLLY.K&)FH$!3ik@bH=m'f)FH7$$"3?***\7o7Tv)FH$!35+kroXh7&)FH7$$"3IKLL$Q*o]*)FH$!3#zX;;]=#Q%)FH7$$"3A++D"=lj;*FH$!3U$\l[A%fc$)FH7$$"3]***\PaR<P*FH$!3um&Q4ho)y#)FH7$$"3!HLLe9Ege*FH$!3Ae"en3qx>)FH7$$"3GLLeR"3Gy*FH$!3;27MDjHB")FH7$$"3cmm;/T1&***FH$!3(\K(f7j'H/)FH7$$"3em;zRQb@5F^v$!3%)=_p0g_fzFH7$$"3%)**\(=>Y2/"F^v$!3/,"\K(4*o)yFH7$$"3imm"zXu91"F^v$!33cbI[JW3yFH7$$"3'******\y))G3"F^v$!3nzO,p))RFxFH7$$"3!****\i_QQ5"F^v$!3]#odH&G6[wFH7$$"3#***\7y%3T7"F^v$!3w:Dhb&*RrvFH7$$"3#****\P![hY6F^v$!3Ge)p"=DA'[(FH7$$"3ELLLQx$o;"F^v$!3HXeihro4uFH7$$"3')****\P+V)="F^v$!3Ja.PK$pzK(FH7$$"3im;zpe*z?"F^v$!3=StSL3#RD(FH7$$"3)*****\#\'QH7F^v$!3%R9p_EmH<(FH7$$"37L$e9S8&\7F^v$!3sA")eDVz'4(FH7$$"3%***\i?=bq7F^v$!3-#ou1qsr,(FH7$$"3GLL$3s?6H"F^v$!3xoP")3!G$RpFH7$$"3&***\7`Wl78F^v$!3#Q&fqI=$y&oFH7$$"3emmm'*RRL8F^v$!3M.w8D8MznFH7$$"3_mmTvJga8F^v$!3+a!flWt!*p'FH7$$"3KL$e9tOcP"F^v$!3&G^TlAq%>mFH7$$"3'******\Qk\R"F^v$!3e0ghMJKYlFH7$$"3@LL3dg6<9F^v$!3-'GCEJ)[ikFH7$$"3_mmmw(GpV"F^v$!3=BFV[a](Q'FH7$$"3-+]7oK0e9F^v$!3&Hhje2evI'FH7$$"3-+](=5s#y9F^v$!3f"4g#R#Q5B'FH7$$"3++++++++:F^v$!3yJ?hCs!)[hFH7S7$F[em$!3m*)f9u(R\P)FH7$$"3hmm;arz@5F^v$!3Ob=vT'p;E)FH7$$"3OL$e9ui2/"F^v$!3)\#y?0R6j")FH7$$"3smm"z_"4i5F^v$!3Y_8%=nxA0)FH7$$"3qmmT&phN3"F^v$!3-+P(Ru12%zFH7$$"3UL$e*=)H\5"F^v$!3F"e]K4m'HyFH7$$"3sm;z/3uC6F^v$!37fv$e><ns(FH7$$"3-+]7LRDX6F^v$!3eM#*fv&>,i(FH7$$"3em;zR'ok;"F^v$!3<)GfU;w)4vFH7$$"3-+]i5`h(="F^v$!33fw$\I')**R(FH7$$"3YLL$3En$47F^v$!3i'oWu2^pG(FH7$$"3cmmT!RE&G7F^v$!3!4_Uve*Q(=(FH7$$"3)*****\K]4]7F^v$!3YHu)4$pIvqFH7$$"3))****\PAvr7F^v$!3%Q%eF_SwipFH7$$"3/++]nHi#H"F^v$!3m<*[\83V&oFH7$$"3bm;z*ev:J"F^v$!3-/Nvr(>ev'FH7$$"3ELL$347TL"F^v$!3>=d">e2(QmFH7$$"3=LLLjM?`8F^v$!30%)=\&>)\RlFH7$$"3#***\7o7Tv8F^v$!3K>h7%4%4CkFH7$$"3ALLLQ*o]R"F^v$!3it\%*4>%>K'FH7$$"3-+]7=lj;9F^v$!3"G-[Oxk)4iFH7$$"3&***\PaR<P9F^v$!3Ib$ff$39.hFH7$$"3GLLe9Ege9F^v$!3'*)\dIg&y"*fFH7$$"3WL$eR"3Gy9F^v$!3U;?"ztE&*)eFH7$$"3mmmT5k]*\"F^v$!3u#yfrtE#zdFH7$$"3em;zRQb@:F^v$!3C"oGc.cYm&FH7$$"3%)**\(=>Y2a"F^v$!3)GhWJ!>#\c&FH7$$"3imm"zXu9c"F^v$!3/ufv2j?daFH7$$"3'******\y))Ge"F^v$!3;=4udb#fM&FH7$$"3!****\i_QQg"F^v$!34z#GS0fqB&FH7$$"3#***\7y%3Ti"F^v$!3Vw\(Q6D<8&FH7$$"3#****\P![hY;F^v$!3'y*)zAtpZ,&FH7$$"3ELLLQx$om"F^v$!3@")f6?,o4\FH7$$"3')****\P+V)o"F^v$!3[9C?GXZ(z%FH7$$"3im;zpe*zq"F^v$!3K$o)*[e*z&p%FH7$$"3)*****\#\'QH<F^v$!3q'*e*f,UYe%FH7$$"37L$e9S8&\<F^v$!3k&GqjS^+[%FH7$$"3%***\i?=bq<F^v$!3[5s*G3C2P%FH7$$"3GLL$3s?6z"F^v$!3'***o)4kOQE%FH7$$"3&***\7`Wl7=F^v$!3]b$>^RN>:%FH7$$"3emmm'*RRL=F^v$!3pi.d&>hT/%FH7$$"3_mmTvJga=F^v$!3#*p*e.^YR$RFH7$$"3KL$e9tOc(=F^v$!3q?tQeWkCQFH7$$"3'******\Qk\*=F^v$!3ibtHCs?CPFH7$$"3@LL3dg6<>F^v$!3a.Up>[44OFH7$$"3_mmmw(Gp$>F^v$!3H1Av7p81NFH7$$"3-+]7oK0e>F^v$!3-Q\z4BO'R$FH7$$"3-+](=5s#y>F^v$!3[36%y+%H"H$FH7$$""#FE$!3gMiMoPQyJFH-%&COLORG62%$RGBG$FEF5F[doF[doF[doF[do$F-F5F\doF[doF[doF[doF\doF[doF\doF[doF\do-%*THICKNESSG6#Fdco-%*GRIDSTYLEG6#%,RECTANGULARG-Fhco6#%%NONEG-%%VIEWG6$;F3$"#DF5;$!2[%QQssyq5!#;$"1%>cIxLa@%F^v
____; _____; _____; _____.
Is 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 increasing or decreasing for x in [0, 2]? _________________
What does this tell you about the derivative of 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?
In this case, at least, the graph of the function lies above its tangent lines, and its second derivative (the derivative of 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), is ___________ .
Let's repeat this reasoning on a function with a different shape.
Case 2: The function is decreasing and the graph of the function lies above its tangent lines.
6,-%+AXESLABELSG6'Q"x6"Q!F'-%%FONTG6$%*HELVETICAG"#5%+HORIZONTALGF.-%%TEXTG6&7$$"#?!""$"2/+++++++$!#<Q)y~=~f(x)F'%+ALIGNRIGHTG-F*6%%&TIMESG%'ITALICG"#7-%'CURVESG6%7S7$$!3++++++++]!#=$"3+++++++]iF87$$!3-+++v`3YVFG$"3_))y'3t=t#fF87$$!3C++Dcx6xPFG$"37!zXzG8Nl&F87$$!3+++]iTDPJFG$"3MO7!=IDLN&F87$$!3y****\P"\J\#FG$"3Kq"=7e<%f]F87$$!3;++DJa5_=FG$"3meYy<^9vZF87$$!3A++Dcexd7FG$"3P`caV.$*=XF87$$!3$>++D1?QU'!#>$"3AQ&>*[$z5E%F87$$!3NI****\i!3%f!#@$"3m)yJanwB+%F87$$"3I)***\(=$f%G'Feo$"3'pB`O)ec_PF87$$"3Q+++Dy,"G"FG$"3mx'zm$H+/NF87$$"33++]7<zb=FG$"3AO=!Q%H7#H$F87$$"3`+++v4&G]#FG$"3o%eI+C-:1$F87$$"3!)*****\7nD:$FG$"3[2jxW*f$QGF87$$"3[+++D!*oyPFG$"3%[bwuH48j#F87$$"3))***\PpnsM%FG$"3MC7^'G!3]CF87$$"39+++DFOB]FG$"3N%>p1k'*HC#F87$$"39++++R5'f&FG$"3!>&ffGAsu?F87$$"3!)***\P/QBE'FG$"3%e)>CgNB()=F87$$"39******\"o?&oFG$"3]WCK>6oG<F87$$"3k++vVb4*\(FG$"3'4"HCAhsi:F87$$"3w++DJ'=_6)FG$"3&4()H=G![79F87$$"3#4++vVy!e()FG$"3GCS</!3QE"F87$$"3'4+](=WU[$*FG$"3c73jB1cM6F87$$"3s****\7B>&)**FG$"3(44w,tjH+"F87$$"3)***\P>:mk5F8$"3oN)yLt!e[()FG7$$"3'***\iv&QA7"F8$"3i*G37=^Yq(FG7$$"31++vtLU%="F8$"3e?L&GL_;l'FG7$$"3!******\Nm'[7F8$"3Qh)*3hC-XcFG7$$"3"****\(yb^68F8$"3+w%RI)z5SZFG7$$"3)***\PMaKs8F8$"3UC`K.OvRRFG7$$"3&****\7TW)R9F8$"3&>fyg$GuPJFG7$$"3z*****\@80]"F8$"3Akj*Q[q[\#FG7$$"31++]7,Hl:F8$"3?EE!H'os*)=FG7$$"3()**\P4w)Ri"F8$"3!oFN!zJ&QT"FG7$$"3;++]x%f")o"F8$"3g!H2t9^Ws*Feo7$$"3!)**\P/-a[<F8$"3k'ow:)G?BjFeo7$$"3/+](=Yb;"=F8$"3qc>:/lOZNFeo7$$"3')****\i@Ot=F8$"3%Qkn')=9Pg"Feo7$$"3')**\PfL'z$>F8$"3_<a.!yW&[Q!#?7$$"3>+++!*>=+?F8$"3^;o+5g.7L!#D7$$"3-++DE&4Q1#F8$"3UU%\-kb;2%Fiy7$$"3=+]P%>5p7#F8$"3\K+jV(>1h"Feo7$$"39+++bJ*[=#F8$"3*zS&ewya=MFeo7$$"33++Dr"[8D#F8$"3jP>2>.f<jFeo7$$"3++++Ijy5BF8$"3[!*o["H9)e'*Feo7$$"31+]P/)fTP#F8$"3O$Q*4#fb**R"FG7$$"31+]i0j"[V#F8$"3mMPP'>_1*=FG7$$"3++++++++DF8$Fe\lFG-%&COLORG6&%$RGBG$""!F5F[]lF[]l-%*THICKNESSG6#"""-FA6%7S7$FE$""'F\]l7$$!3MLLLe%G?y%FG$"3cLLL$Q6G"fF87$$!3OmmT&esBf%FG$"3bmm;M!\p$eF87$$!3KLL$3s%3zVFG$"37LLL))Qj^dF87$$!33LL$e/$QkTFG$"3ALLL=KvlcF87$$!3!pm;/"=q]RFG$"3Kmm;C2G!e&F87$$!3SLL3_>f_PFG$"39LL$3yO5]&F87$$!3))***\(o1YZNFG$"3&*****\nU)*=aF87$$!3]LL3-OJNLFG$"3iLL$3WDTL&F87$$!3C++v$*o%Q7$FG$"3))****\d(Q&\_F87$$!3ammm"RFj!HFG$"3;mmmc4`i^F87$$!3JLL$e4OZr#FG$"3wLLLQW*e3&F87$$!3=+++v'\!*\#FG$"33+++q)>'**\F87$$!33+++DwZ#G#FG$"3Z+++]5*H"\F87$$!3-+++D.xt?FG$"3z******H"3&H[F87$$!3OLL3-TC%)=FG$"3!QLL3k(p`ZF87$$!3!omm;4z)e;FG$"3%pmmmj^Nm%F87$$!3+nmmm`'zY"FG$"3CnmmYh=(e%F87$$!3E++v=t)eC"FG$"3K++]F\N)\%F87$$!39nmm;1J\5FG$"33nmmYUs>WF87$$!3&y***\(=[jL)Feo$"3"*****\FRXLVF87$$!3M****\iXg#G'Feo$"3?++]#=/8D%F87$$!3WlmmT&Q(RTFeo$"3%omm;a*elTF87$$!3;nm;/'=><#Feo$"3Cmm;Wn(o3%F87$$!3vDMLLe*e$\F[p$"3PLLLeV(>+%F87$$"3[em;zRQb@Feo$"3mLL$3k%y8RF87$$"3'[***\(=>Y2%Feo$"3?++]K_,PQF87$$"3Qhmm"zXu9'Feo$"3aLLLo@5aPF87$$"3]'******\y))G)Feo$"39+++g[WoOF87$$"3'*)***\i_QQ5FG$"3U+++&*ek%e$F87$$"3@***\7y%3T7FG$"3J++](3mN]$F87$$"35****\P![hY"FG$"3O+++&ySNT$F87$$"3kKLL$Qx$o;FG$"3&pmmm/\EL$F87$$"3!)*****\P+V)=FG$"33+++])ziC$F87$$"3?mm"zpe*z?FG$"3_LL$3_;!oJF87$$"3%)*****\#\'QH#FG$"31+++ISX#3$F87$$"3GKLe9S8&\#FG$"34nm;%RY>+$F87$$"3R***\i?=bq#FG$"3C++]<Fz<HF87$$"3"HLL$3s?6HFG$"3$ommm6<b$GF87$$"3a***\7`Wl7$FG$"3=++](=#Q\FF87$$"3#pmmm'*RRL$FG$"3ALLL8SUmEF87$$"3Qmm;a<.YNFG$"3WLLL)H(e"e#F87$$"3=LLe9tOcPFG$"3smm;uIX(\#F87$$"3u******\Qk\RFG$"35+++gC9?CF87$$"3CLL$3dg6<%FG$"3qmmmrd`JBF87$$"3ImmmmxGpVFG$"3[LLL$*[G_AF87$$"3A++D"oK0e%FG$"3!*****\Fpyn@F87$$"3A++v=5s#y%FG$"3#*****\#f6p3#F87$$"3++++++++]FG$""#F\]l-Fh\l6&Fj\lF[]lF[]l$F-F5-F^]l6#Ff\m-FA6%7S7$$F\]lF\]l$"3+++++++]PF87$$"3emmm;arz@Feo$"3%*****\P&3Yo$F87$$"3[LL$e9ui2%Feo$"3"***\iv<rFOF87$$"3nmmm"z_"4iFeo$"31++D;asjNF87$$"3[mmmT&phN)Feo$"39++v8\J*\$F87$$"3CLLe*=)H\5FG$"3=+]7V0@NMF87$$"3gmm"z/3uC"FG$"3')**\i&exdP$F87$$"3%)***\7LRDX"FG$"3>+]i+#QUJ$F87$$"3]mm"zR'ok;FG$"3++]i!3%f]KF87$$"3w***\i5`h(=FG$"3M+]7oS:(=$F87$$"3WLLL3En$4#FG$"32++]<#)*=7$F87$$"3qmm;/RE&G#FG$"3))***\(G3UkIF87$$"3")*****\K]4]#FG$"31++]-\r**HF87$$"3$******\PAvr#FG$"3"*****\(GVZ$HF87$$"3)******\nHi#HFG$"31++](4J@(GF87$$"3jmm"z*ev:JFG$"3!***\iIKF:GF87$$"3?LLL347TLFG$"3+++]FPmZFF87$$"3,LLLLY.KNFG$"3)*******4'*Q!p#F87$$"3w***\7o7Tv$FG$"3-+]i&>mPi#F87$$"3'GLLLQ*o]RFG$"33+++&=$zkDF87$$"3A++D"=lj;%FG$"3;+]iX/4+DF87$$"31++vV&R<P%FG$"39+](o8y%QCF87$$"3WLL$e9Ege%FG$"3!****\i:#>uBF87$$"3GLLeR"3Gy%FG$"38+]7ev::BF87$$"3cmm;/T1&*\FG$"3/++vo2[^AF87$$"3&em;zRQb@&FG$"3-+]i![Q`=#F87$$"3\***\(=>Y2aFG$"30+]PC9wF@F87$$"39mm;zXu9cFG$"3Q++DEmdl?F87$$"3l******\y))GeFG$"3))*****\kL8+#F87$$"3'*)***\i_QQgFG$"3J++D@W[Q>F87$$"3@***\7y%3TiFG$"3C+]ilXnx=F87$$"35****\P![hY'FG$"3F++v)eb,"=F87$$"3kKLL$Qx$omFG$"3A+++&y'[\<F87$$"3!)*****\P+V)oFG$"3%*****\())4Zo"F87$$"3?mm"zpe*zqFG$"39+]i!R7gi"F87$$"3%)*****\#\'QH(FG$"3#)****\A0%=c"F87$$"3GKLe9S8&\(FG$"3?+]i&zf9]"F87$$"3R***\i?=bq(FG$"3S+]7QXMQ9F87$$"3"HLL$3s?6zFG$"37++]Pyjw8F87$$"3a***\7`Wl7)FG$"39+]iSm.78F87$$"3#pmmm'*RRL)FG$"3#)******4!=)\7F87$$"3Qmm;a<.Y&)FG$"3'****\PZ!>'="F87$$"3=LLe9tOc()FG$"3$)**\i0)*3B6F87$$"3u******\Qk\*)FG$"3')*****\%o5l5F87$$"3CLL$3dg6<*FG$"39****\(G=l)**FG7$$"3ImmmmxGp$*FG$"3+++++n8#R*FG7$$"3A++D"oK0e*FG$"3G***\i&>Se()FG7$$"3A++v=5s#y*FG$"3M***\P%p$=:)FG7$$F`]lF\]l$"3++++++++vFG-Fh\l6&Fj\lFi\mF[]lF[]lFj\m-FA6%7SFb\m7$$"35mmmT:(z@&FG$"3ymmm"p0k&>F87$$"3jLLe9ui2aFG$"3FLL3<XZ=>F87$$"3Anm;z_"4i&FG$"3cmm;Wp"e(=F87$$"3$pmmT&phNeFG$"3hmm;4m(G$=F87$$"35LLe*=)H\gFG$"3QLL3i.9!z"F87$$"3;nm"z/3uC'FG$"3emmT!R=0v"F87$$"37++DJ$RDX'FG$"3)****\P8#\4<F87$$"3'fm;zR'okmFG$"3!om;/siqm"F87$$"3I++D1J:woFG$"3%****\(y$pZi"F87$$"3WLLL3En$4(FG$"3ILLLyaE"e"F87$$"3qmm;/RE&G(FG$"3mmm;>s%Ha"F87$$"3")*****\K]4](FG$"3/+++N*4)*\"F87$$"3$******\PAvr(FG$"3-+++Db\c9F87$$"3`+++v'Hi#zFG$"3*)*****\1aZT"F87$$"3jmm"z*ev:")FG$"3ommT?)[oP"F87$$"3kKLL347T$)FG$"3ZLLL=exJ8F87$$"3,LLLLY.K&)FG$"3SLLLtIf$H"F87$$"3?***\7o7Tv)FG$"3;++vju<\7F87$$"3IKLL$Q*o]*)FG$"3aLLLB@')47F87$$"3A++D"=lj;*FG$"3'****\P'psm6F87$$"3]***\PaR<P*FG$"35++D"4_c7"F87$$"3!HLLe9Ege*FG$"3ULL$3x%z#3"F87$$"3GLLeR"3Gy*FG$"3MLL3s$QM/"F87$$"3cmm;/T1&***FG$"3pmm;zr)4+"F87$$"3em;zRQb@5F8$"3Iom;/K#*o&*FG7$$"3%)**\(=>Y2/"F8$"3C.+]ih2&=*FG7$$"3imm"zXu91"F8$"3snmmT3^q()FG7$$"3'******\y))G3"F8$"3q++++VAU$)FG7$$"3!****\i_QQ5"F8$"33-++v%HK#zFG7$$"3#***\7y%3T7"F8$"3d,+]P/$y^(FG7$$"3#****\P![hY6F8$"3y,++DRqnqFG7$$"3ELLLQx$o;"F8$"3uMLLL_CjmFG7$$"3')****\P+V)="F8$"3h-++]#*RJiFG7$$"3im;zpe*z?"F8$"3enm;/E3SeFG7$$"3)*****\#\'QH7F8$"3M+++],F7aFG7$$"37L$e9S8&\7F8$"3mPL$3(>t4]FG7$$"3%***\i?=bq7F8$"3?,+](ej*)e%FG7$$"3GLL$3s?6H"F8$"3=MLL$e&exTFG7$$"3&***\7`Wl78F8$"3#4++v$4"pu$FG7$$"3emmm'*RRL8F8$"3Qommm+7KLFG7$$"3_mmTvJga8F8$"3Xpmm"\Oz!HFG7$$"3KL$e9tOcP"F8$"3mLL$3Pls[#FG7$$"3'******\Qk\R"F8$"3`++++Br+@FG7$$"3@LL3dg6<9F8$"3sNLLe)ywl"FG7$$"3_mmmw(GpV"F8$"3kpmmmWUh7FG7$$"3-+]7oK0e9F8$"3E&****\PY$*Q)Feo7$$"3-+](=5s#y9F8$"3i&****\izbM%Feo7$$"3++++++++:F8F`]m-Fh\l6&Fj\lF[]lFi\mF[]lFj\m-FA6%7SF^\n7$$"3hmm;arz@5F8$"3!RLL$e%G?G(FG7$$"3OL$e9ui2/"F8$"3OmmT&esB4(FG7$$"3smm"z_"4i5F8$"3yKL$3s%3zoFG7$$"3qmmT&phN3"F8$"33LL$e/$QkmFG7$$"3UL$e*=)H\5"F8$"3!em;/"=q]kFG7$$"3sm;z/3uC6F8$"3'GL$3_>f_iFG7$$"3-+]7LRDX6F8$"3))***\(o1YZgFG7$$"3em;zR'ok;"F8$"30ML3-OJNeFG7$$"3-+]i5`h(="F8$"3p***\P*o%Qi&FG7$$"3YLL$3En$47F8$"3Vlmm"RFjS&FG7$$"3cmmT!RE&G7F8$"3UML$e4OZ@&FG7$$"3)*****\K]4]7F8$"3=+++v'\!**\FG7$$"3))****\PAvr7F8$"3=,++DwZ#y%FG7$$"3/++]nHi#H"F8$"3[*****\KqPd%FG7$$"3bm;z*ev:J"F8$"3[ML3-TC%Q%FG7$$"3ELL$347TL"F8$"3Onmm"4z)eTFG7$$"3=LLLjM?`8F8$"35ommm`'z'RFG7$$"3#***\7o7Tv8F8$"3!3+](=t)eu$FG7$$"3ALLLQ*o]R"F8$"3qnmm;1J\NFG7$$"3-+]7=lj;9F8$"3y***\(=[jLLFG7$$"3&***\PaR<P9F8$"3\++Dc/EGJFG7$$"3GLLe9Ege9F8$"35nm;aQ(R"HFG7$$"3WL$eR"3Gy9F8$"3hlmTg=><FFG7$$"3mmmT5k]*\"F8$"3VLL$e*e$\]#FG7$$"3em;zRQb@:F8$"3;ML3-;Y%G#FG7$$"3%)**\(=>Y2a"F8$"3i,+D"3QD4#FG7$$"3imm"zXu9c"F8$"3'QLL3Ub_)=FG7$$"3'******\y))Ge"F8$"3O+++]@6r;FG7$$"3!****\i_QQg"F8$"3/,+]PZhh9FG7$$"3#***\7y%3Ti"F8$"3y++v=_"*e7FG7$$"3#****\P![hY;F8$"3*3++D'>&Q."FG7$$"3ELLLQx$om"F8$"3ptmmmhA;$)Feo7$$"3')****\P+V)o"F8$"318++]i*p:'Feo7$$"3im;zpe*zq"F8$"3!zLL3-8/?%Feo7$$"3)*****\#\'QH<F8$"3o,++]2Nh?Feo7$$"37L$e9S8&\<F8$"3oF)omT&)f'[F[p7$$"3%***\i?=bq<F8$!3#R***\i?=b?Feo7$$"3GLL$3s?6z"F8$!33HLL$3s?6%Feo7$$"3&***\7`Wl7=F8$!3Q&***\7`WliFeo7$$"3emmm'*RRL=F8$!36emmm'*RR$)Feo7$$"3_mmTvJga=F8$!3Glm;a<.Y5FG7$$"3KL$e9tOc(=F8$!3=LLe9tOc7FG7$$"3'******\Qk\*=F8$!3u******\Qk\9FG7$$"3@LL3dg6<>F8$!39KL$3dg6n"FG7$$"3_mmmw(Gp$>F8$!3=lmmmxGp=FG7$$"3-+]7oK0e>F8$!3A++D"oK03#FG7$$"3-+](=5s#y>F8$!3A++v=5s#G#FG7$Fe\m$!3++++++++DFG-Fh\l6&Fj\lFi\mF[]lFi\mFj\m-%*GRIDSTYLEG6#%,RECTANGULARG-Fh\l6#%%NONEG-%%VIEWG6$;$!"&F5$"#DF5;$!#Q!"#$"1++++++!Q'!#:
Again, estimate the slopes of the tangent lines at the various x-values:
____; _____; _____; _____.
Is the first derivative increasing or decreasing?
What does this tell you about the second derivative?
What is connection between the graph of the function lying above its tangent lines and the sign (positive/ negative) of the second derivative?
We've now examined two cases carefully. We have two more to go:
Case 3: The function is increasing and the graph of the function lies below its tangent lines.
Case 4: The function is decreasing and the graph of the function lies below its tangent lines.
What do you think you will find about whether the first derivative is increasing/ decreasing for Cases 3 and 4?
What would this tell you about the sign of the second derivative in Cases 3 and 4?
Use the graphs below to check and see if you're right.
Case 3: the function is increasing and the graph of the function lies below its tangent lines.
6(-%+AXESLABELSG6'Q"x6"Q!F'-%%FONTG6$%*HELVETICAG"#5%+HORIZONTALGF.-%%TEXTG6&7$$"2/++++++I#!#;$!#5!""Q)y~=~f(x)F'%+ALIGNRIGHTG-F*6%%&TIMESG%'ITALICG"#7-%'CURVESG6)7S7$$!3++++++++]!#=$!3+++++++]i!#<7$$!3-+++v`3YVFG$!3_))y'3t=t#fFJ7$$!3C++Dcx6xPFG$!37!zXzG8Nl&FJ7$$!3+++]iTDPJFG$!3MO7!=IDLN&FJ7$$!3y****\P"\J\#FG$!3Kq"=7e<%f]FJ7$$!3;++DJa5_=FG$!3meYy<^9vZFJ7$$!3A++Dcexd7FG$!3P`caV.$*=XFJ7$$!3$>++D1?QU'!#>$!3AQ&>*[$z5E%FJ7$$!3NI****\i!3%f!#@$!3m)yJanwB+%FJ7$$"3I)***\(=$f%G'Ffo$!3'pB`O)ec_PFJ7$$"3Q+++Dy,"G"FG$!3mx'zm$H+/NFJ7$$"33++]7<zb=FG$!3AO=!Q%H7#H$FJ7$$"3`+++v4&G]#FG$!3o%eI+C-:1$FJ7$$"3!)*****\7nD:$FG$!3[2jxW*f$QGFJ7$$"3[+++D!*oyPFG$!3%[bwuH48j#FJ7$$"3))***\PpnsM%FG$!3MC7^'G!3]CFJ7$$"39+++DFOB]FG$!3N%>p1k'*HC#FJ7$$"39++++R5'f&FG$!3!>&ffGAsu?FJ7$$"3!)***\P/QBE'FG$!3%e)>CgNB()=FJ7$$"39******\"o?&oFG$!3]WCK>6oG<FJ7$$"3k++vVb4*\(FG$!3'4"HCAhsi:FJ7$$"3w++DJ'=_6)FG$!3&4()H=G![79FJ7$$"3#4++vVy!e()FG$!3GCS</!3QE"FJ7$$"3'4+](=WU[$*FG$!3c73jB1cM6FJ7$$"3s****\7B>&)**FG$!3(44w,tjH+"FJ7$$"3)***\P>:mk5FJ$!3oN)yLt!e[()FG7$$"3'***\iv&QA7"FJ$!3i*G37=^Yq(FG7$$"31++vtLU%="FJ$!3e?L&GL_;l'FG7$$"3!******\Nm'[7FJ$!3Qh)*3hC-XcFG7$$"3"****\(yb^68FJ$!3+w%RI)z5SZFG7$$"3)***\PMaKs8FJ$!3UC`K.OvRRFG7$$"3&****\7TW)R9FJ$!3&>fyg$GuPJFG7$$"3z*****\@80]"FJ$!3Akj*Q[q[\#FG7$$"31++]7,Hl:FJ$!3?EE!H'os*)=FG7$$"3()**\P4w)Ri"FJ$!3!oFN!zJ&QT"FG7$$"3;++]x%f")o"FJ$!3g!H2t9^Ws*Ffo7$$"3!)**\P/-a[<FJ$!3k'ow:)G?BjFfo7$$"3/+](=Yb;"=FJ$!3qc>:/lOZNFfo7$$"3')****\i@Ot=FJ$!3%Qkn')=9Pg"Ffo7$$"3')**\PfL'z$>FJ$!3_<a.!yW&[Q!#?7$$"3>+++!*>=+?FJ$!3^;o+5g.7L!#D7$$"3-++DE&4Q1#FJ$!3UU%\-kb;2%Fjy7$$"3=+]P%>5p7#FJ$!3\K+jV(>1h"Ffo7$$"39+++bJ*[=#FJ$!3*zS&ewya=MFfo7$$"33++Dr"[8D#FJ$!3jP>2>.f<jFfo7$$"3++++Ijy5BFJ$!3[!*o["H9)e'*Ffo7$$"31+]P/)fTP#FJ$!3O$Q*4#fb**R"FG7$$"31+]i0j"[V#FJ$!3mMPP'>_1*=FG7$$"3++++++++DFJ$!3++++++++DFG7S7$FE$!"'""!7$$!3MLLLe%G?y%FG$!3cLLL$Q6G"fFJ7$$!3OmmT&esBf%FG$!3bmm;M!\p$eFJ7$$!3KLL$3s%3zVFG$!37LLL))Qj^dFJ7$$!33LL$e/$QkTFG$!3ALLL=KvlcFJ7$$!3!pm;/"=q]RFG$!3Kmm;C2G!e&FJ7$$!3SLL3_>f_PFG$!39LL$3yO5]&FJ7$$!3))***\(o1YZNFG$!3&*****\nU)*=aFJ7$$!3]LL3-OJNLFG$!3iLL$3WDTL&FJ7$$!3C++v$*o%Q7$FG$!3))****\d(Q&\_FJ7$$!3ammm"RFj!HFG$!3;mmmc4`i^FJ7$$!3JLL$e4OZr#FG$!3wLLLQW*e3&FJ7$$!3=+++v'\!*\#FG$!33+++q)>'**\FJ7$$!33+++DwZ#G#FG$!3Z+++]5*H"\FJ7$$!3-+++D.xt?FG$!3z******H"3&H[FJ7$$!3OLL3-TC%)=FG$!3!QLL3k(p`ZFJ7$$!3!omm;4z)e;FG$!3%pmmmj^Nm%FJ7$$!3+nmmm`'zY"FG$!3CnmmYh=(e%FJ7$$!3E++v=t)eC"FG$!3K++]F\N)\%FJ7$$!39nmm;1J\5FG$!33nmmYUs>WFJ7$$!3&y***\(=[jL)Ffo$!3"*****\FRXLVFJ7$$!3M****\iXg#G'Ffo$!3?++]#=/8D%FJ7$$!3WlmmT&Q(RTFfo$!3%omm;a*elTFJ7$$!3;nm;/'=><#Ffo$!3Cmm;Wn(o3%FJ7$$!3vDMLLe*e$\F\p$!3PLLLeV(>+%FJ7$$"3[em;zRQb@Ffo$!3mLL$3k%y8RFJ7$$"3'[***\(=>Y2%Ffo$!3?++]K_,PQFJ7$$"3Qhmm"zXu9'Ffo$!3aLLLo@5aPFJ7$$"3]'******\y))G)Ffo$!39+++g[WoOFJ7$$"3'*)***\i_QQ5FG$!3U+++&*ek%e$FJ7$$"3@***\7y%3T7FG$!3J++](3mN]$FJ7$$"35****\P![hY"FG$!3O+++&ySNT$FJ7$$"3kKLL$Qx$o;FG$!3&pmmm/\EL$FJ7$$"3!)*****\P+V)=FG$!33+++])ziC$FJ7$$"3?mm"zpe*z?FG$!3_LL$3_;!oJFJ7$$"3%)*****\#\'QH#FG$!31+++ISX#3$FJ7$$"3GKLe9S8&\#FG$!34nm;%RY>+$FJ7$$"3R***\i?=bq#FG$!3C++]<Fz<HFJ7$$"3"HLL$3s?6HFG$!3$ommm6<b$GFJ7$$"3a***\7`Wl7$FG$!3=++](=#Q\FFJ7$$"3#pmmm'*RRL$FG$!3ALLL8SUmEFJ7$$"3Qmm;a<.YNFG$!3WLLL)H(e"e#FJ7$$"3=LLe9tOcPFG$!3smm;uIX(\#FJ7$$"3u******\Qk\RFG$!35+++gC9?CFJ7$$"3CLL$3dg6<%FG$!3qmmmrd`JBFJ7$$"3ImmmmxGpVFG$!3[LLL$*[G_AFJ7$$"3A++D"oK0e%FG$!3!*****\Fpyn@FJ7$$"3A++v=5s#y%FG$!3#*****\#f6p3#FJ7$$"3++++++++]FG$!"#F]]l7S7$$F]]lF]]l$!3+++++++]PFJ7$$"3emmm;arz@Ffo$!3%*****\P&3Yo$FJ7$$"3[LL$e9ui2%Ffo$!3"***\iv<rFOFJ7$$"3nmmm"z_"4iFfo$!31++D;asjNFJ7$$"3[mmmT&phN)Ffo$!39++v8\J*\$FJ7$$"3CLLe*=)H\5FG$!3=+]7V0@NMFJ7$$"3gmm"z/3uC"FG$!3')**\i&exdP$FJ7$$"3%)***\7LRDX"FG$!3>+]i+#QUJ$FJ7$$"3]mm"zR'ok;FG$!3++]i!3%f]KFJ7$$"3w***\i5`h(=FG$!3M+]7oS:(=$FJ7$$"3WLLL3En$4#FG$!32++]<#)*=7$FJ7$$"3qmm;/RE&G#FG$!3))***\(G3UkIFJ7$$"3")*****\K]4]#FG$!31++]-\r**HFJ7$$"3$******\PAvr#FG$!3"*****\(GVZ$HFJ7$$"3)******\nHi#HFG$!31++](4J@(GFJ7$$"3jmm"z*ev:JFG$!3!***\iIKF:GFJ7$$"3?LLL347TLFG$!3+++]FPmZFFJ7$$"3,LLLLY.KNFG$!3)*******4'*Q!p#FJ7$$"3w***\7o7Tv$FG$!3-+]i&>mPi#FJ7$$"3'GLLLQ*o]RFG$!33+++&=$zkDFJ7$$"3A++D"=lj;%FG$!3;+]iX/4+DFJ7$$"31++vV&R<P%FG$!39+](o8y%QCFJ7$$"3WLL$e9Ege%FG$!3!****\i:#>uBFJ7$$"3GLLeR"3Gy%FG$!38+]7ev::BFJ7$$"3cmm;/T1&*\FG$!3/++vo2[^AFJ7$$"3&em;zRQb@&FG$!3-+]i![Q`=#FJ7$$"3\***\(=>Y2aFG$!30+]PC9wF@FJ7$$"39mm;zXu9cFG$!3Q++DEmdl?FJ7$$"3l******\y))GeFG$!3))*****\kL8+#FJ7$$"3'*)***\i_QQgFG$!3J++D@W[Q>FJ7$$"3@***\7y%3TiFG$!3C+]ilXnx=FJ7$$"35****\P![hY'FG$!3F++v)eb,"=FJ7$$"3kKLL$Qx$omFG$!3A+++&y'[\<FJ7$$"3!)*****\P+V)oFG$!3%*****\())4Zo"FJ7$$"3?mm"zpe*zqFG$!39+]i!R7gi"FJ7$$"3%)*****\#\'QH(FG$!3#)****\A0%=c"FJ7$$"3GKLe9S8&\(FG$!3?+]i&zf9]"FJ7$$"3R***\i?=bq(FG$!3S+]7QXMQ9FJ7$$"3"HLL$3s?6zFG$!37++]Pyjw8FJ7$$"3a***\7`Wl7)FG$!39+]iSm.78FJ7$$"3#pmmm'*RRL)FG$!3#)******4!=)\7FJ7$$"3Qmm;a<.Y&)FG$!3'****\PZ!>'="FJ7$$"3=LLe9tOc()FG$!3$)**\i0)*3B6FJ7$$"3u******\Qk\*)FG$!3')*****\%o5l5FJ7$$"3CLL$3dg6<*FG$!39****\(G=l)**FG7$$"3ImmmmxGp$*FG$!3+++++n8#R*FG7$$"3A++D"oK0e*FG$!3G***\i&>Se()FG7$$"3A++v=5s#y*FG$!3M***\P%p$=:)FG7$$"""F]]l$!3++++++++vFG7SFi[m7$$"35mmmT:(z@&FG$!3ymmm"p0k&>FJ7$$"3jLLe9ui2aFG$!3FLL3<XZ=>FJ7$$"3Anm;z_"4i&FG$!3cmm;Wp"e(=FJ7$$"3$pmmT&phNeFG$!3hmm;4m(G$=FJ7$$"35LLe*=)H\gFG$!3QLL3i.9!z"FJ7$$"3;nm"z/3uC'FG$!3emmT!R=0v"FJ7$$"37++DJ$RDX'FG$!3)****\P8#\4<FJ7$$"3'fm;zR'okmFG$!3!om;/siqm"FJ7$$"3I++D1J:woFG$!3%****\(y$pZi"FJ7$$"3WLLL3En$4(FG$!3ILLLyaE"e"FJ7$$"3qmm;/RE&G(FG$!3mmm;>s%Ha"FJ7$$"3")*****\K]4](FG$!3/+++N*4)*\"FJ7$$"3$******\PAvr(FG$!3-+++Db\c9FJ7$$"3`+++v'Hi#zFG$!3*)*****\1aZT"FJ7$$"3jmm"z*ev:")FG$!3ommT?)[oP"FJ7$$"3kKLL347T$)FG$!3ZLLL=exJ8FJ7$$"3,LLLLY.K&)FG$!3SLLLtIf$H"FJ7$$"3?***\7o7Tv)FG$!3;++vju<\7FJ7$$"3IKLL$Q*o]*)FG$!3aLLLB@')47FJ7$$"3A++D"=lj;*FG$!3'****\P'psm6FJ7$$"3]***\PaR<P*FG$!35++D"4_c7"FJ7$$"3!HLLe9Ege*FG$!3ULL$3x%z#3"FJ7$$"3GLLeR"3Gy*FG$!3MLL3s$QM/"FJ7$$"3cmm;/T1&***FG$!3pmm;zr)4+"FJ7$$"3em;zRQb@5FJ$!3Iom;/K#*o&*FG7$$"3%)**\(=>Y2/"FJ$!3C.+]ih2&=*FG7$$"3imm"zXu91"FJ$!3snmmT3^q()FG7$$"3'******\y))G3"FJ$!3q++++VAU$)FG7$$"3!****\i_QQ5"FJ$!33-++v%HK#zFG7$$"3#***\7y%3T7"FJ$!3d,+]P/$y^(FG7$$"3#****\P![hY6FJ$!3y,++DRqnqFG7$$"3ELLLQx$o;"FJ$!3uMLLL_CjmFG7$$"3')****\P+V)="FJ$!3h-++]#*RJiFG7$$"3im;zpe*z?"FJ$!3enm;/E3SeFG7$$"3)*****\#\'QH7FJ$!3M+++],F7aFG7$$"37L$e9S8&\7FJ$!3mPL$3(>t4]FG7$$"3%***\i?=bq7FJ$!3?,+](ej*)e%FG7$$"3GLL$3s?6H"FJ$!3=MLL$e&exTFG7$$"3&***\7`Wl78FJ$!3#4++v$4"pu$FG7$$"3emmm'*RRL8FJ$!3Qommm+7KLFG7$$"3_mmTvJga8FJ$!3Xpmm"\Oz!HFG7$$"3KL$e9tOcP"FJ$!3mLL$3Pls[#FG7$$"3'******\Qk\R"FJ$!3`++++Br+@FG7$$"3@LL3dg6<9FJ$!3sNLLe)ywl"FG7$$"3_mmmw(GpV"FJ$!3kpmmmWUh7FG7$$"3-+]7oK0e9FJ$!3E&****\PY$*Q)Ffo7$$"3-+](=5s#y9FJ$!3i&****\izbM%Ffo7$$"3++++++++:FJF`\m7SF^[n7$$"3hmm;arz@5FJ$!3!RLL$e%G?G(FG7$$"3OL$e9ui2/"FJ$!3OmmT&esB4(FG7$$"3smm"z_"4i5FJ$!3yKL$3s%3zoFG7$$"3qmmT&phN3"FJ$!33LL$e/$QkmFG7$$"3UL$e*=)H\5"FJ$!3!em;/"=q]kFG7$$"3sm;z/3uC6FJ$!3'GL$3_>f_iFG7$$"3-+]7LRDX6FJ$!3))***\(o1YZgFG7$$"3em;zR'ok;"FJ$!30ML3-OJNeFG7$$"3-+]i5`h(="FJ$!3p***\P*o%Qi&FG7$$"3YLL$3En$47FJ$!3Vlmm"RFjS&FG7$$"3cmmT!RE&G7FJ$!3UML$e4OZ@&FG7$$"3)*****\K]4]7FJ$!3=+++v'\!**\FG7$$"3))****\PAvr7FJ$!3=,++DwZ#y%FG7$$"3/++]nHi#H"FJ$!3[*****\KqPd%FG7$$"3bm;z*ev:J"FJ$!3[ML3-TC%Q%FG7$$"3ELL$347TL"FJ$!3Onmm"4z)eTFG7$$"3=LLLjM?`8FJ$!35ommm`'z'RFG7$$"3#***\7o7Tv8FJ$!3!3+](=t)eu$FG7$$"3ALLLQ*o]R"FJ$!3qnmm;1J\NFG7$$"3-+]7=lj;9FJ$!3y***\(=[jLLFG7$$"3&***\PaR<P9FJ$!3\++Dc/EGJFG7$$"3GLLe9Ege9FJ$!35nm;aQ(R"HFG7$$"3WL$eR"3Gy9FJ$!3hlmTg=><FFG7$$"3mmmT5k]*\"FJ$!3VLL$e*e$\]#FG7$$"3em;zRQb@:FJ$!3;ML3-;Y%G#FG7$$"3%)**\(=>Y2a"FJ$!3i,+D"3QD4#FG7$$"3imm"zXu9c"FJ$!3'QLL3Ub_)=FG7$$"3'******\y))Ge"FJ$!3O+++]@6r;FG7$$"3!****\i_QQg"FJ$!3/,+]PZhh9FG7$$"3#***\7y%3Ti"FJ$!3y++v=_"*e7FG7$$"3#****\P![hY;FJ$!3*3++D'>&Q."FG7$$"3ELLLQx$om"FJ$!3ptmmmhA;$)Ffo7$$"3')****\P+V)o"FJ$!318++]i*p:'Ffo7$$"3im;zpe*zq"FJ$!3!zLL3-8/?%Ffo7$$"3)*****\#\'QH<FJ$!3o,++]2Nh?Ffo7$$"37L$e9S8&\<FJ$!3oF)omT&)f'[F\p7$$"3%***\i?=bq<FJ$"3#R***\i?=b?Ffo7$$"3GLL$3s?6z"FJ$"33HLL$3s?6%Ffo7$$"3&***\7`Wl7=FJ$"3Q&***\7`WliFfo7$$"3emmm'*RRL=FJ$"36emmm'*RR$)Ffo7$$"3_mmTvJga=FJ$"3Glm;a<.Y5FG7$$"3KL$e9tOc(=FJ$"3=LLe9tOc7FG7$$"3'******\Qk\*=FJ$"3u******\Qk\9FG7$$"3@LL3dg6<>FJ$"39KL$3dg6n"FG7$$"3_mmmw(Gp$>FJ$"3=lmmmxGp=FG7$$"3-+]7oK0e>FJ$"3A++D"oK03#FG7$$"3-+](=5s#y>FJ$"3A++v=5s#G#FG7$$""#F]]l$Ff\lFG-%&COLORG62%$RGBG$F]]lF8FfioFfioFfioFfio$F-F8FgioFfioFfioFfioFgioFfioFgioFfioFgio-%*THICKNESSG6#F`io-%*GRIDSTYLEG6#%,RECTANGULARG-Fcio6#%%NONEG-%%VIEWG6$;$!"&F8$"#DF8;$!1)***********zj!#:$"#QF]\m
Case 4: the function is decreasing and the graph of the function lies below its tangent lines.
6'-%+AXESLABELSG6'Q"x6"Q!F'-%%FONTG6$%*HELVETICAG"#5%+HORIZONTALGF.-%'CURVESG6)7S7$$!""""!$!3+++++++]i!#<7$$!3Umm;/'*4P#*!#=$!3agHAs*pV(eF97$$!3UL$e*[SIt&)F=$!3%QNYyj1qb&F97$$!3%pm;H_'zEyF=$!3!\S')\RE1@&F97$$!3)om;/mS`2(F=$!3u`Wt_m?t[F97$$!3]K$ekLcuK'F=$!3an`$y$Rg[XF97$$!3>n;HK=2McF=$!3uB<!Q?\wD%F97$$!3e**\iSB6;\F=$!3m`Rk2`^mRF97$$!3%em"H2wftTF=$!3-2M1_%oin$F97$$!3,+]7GTYLMF=$!3%>rGw*f#zR$F97$$!3KKL$3(e9sEF=$!3c:,!oRZI7$F97$$!3-mmTNjd,?F=$!3-++*)yf`!*GF97$$!3Y)***\iQnY7F=$!3(fSWf6W&REF97$$!3u'****\(or')[!#>$!3)3kJk]*)*)R#F97$$"3W2++D'Q!=CFdp$!37*>HB`V!y@F97$$"3aPL3FkX^!*Fdp$!3qQE`$>\m)>F97$$"3cnm;zJ#Rp"F=$!3u!=>O!o^q<F97$$"3Iomm;77iBF=$!3knAU,)frf"F97$$"3^+]P%Q%RRJF=$!3l_Rpb'RnS"F97$$"3SmmmTGTFQF=$!3=\b5QqE[7F97$$"3'=+vV8yAe%F=$!3!>@&p)G*G&3"F97$$"3t-]7.%)3,`F=$!3DJ'*R;'))oS*F=7$$"3[omT5:4^gF=$!3hiO\:jH3!)F=7$$"3;o;a)[G)RnF=$!3Q#yq)RL/BoF=7$$"3-LLekVs#[(F=$!3]0H)yHV4l&F=7$$"3!QL3FR%Qa#)F=$!3e"pL@*HL]XF=7$$"3)4+Dcr;h#*)F=$!3w-5A:e?*o$F=7$$"3#[L$3Fgg^'*F=$!3?JJ&*3=`gGF=7$$"3******\Z26S5F9$!3s(3]cC")\6#F=7$$"3>+](=%[V86F9$!3=h?w9iK%\"F=7$$"3G+vVt'zV="F9$!37'*=%R0>;'**Fdp7$$"3#***\78=:j7F9$!3>'\(fijq4cFdp7$$"3Umm;%3KRL"F9$!3g;F#pEbyv#Fdp7$$"3V++DJ^]49F9$!3/\'z+F@$*=)!#?7$$"3=L3FWb)zZ"F9$!3EhW^5EOY[!#@7$$"3]++vBF&Gb"F9$!3[mQz2/T$z#F[w7$$"3emT50pHB;F9$!3'eeE3o7-_"Fdp7$$"35+v=s8$pp"F9$!3ap^;Nl>yQFdp7$$"3umm"H_A*o<F9$!38:l=LB$>B(Fdp7$$"3$)*\Pfe!HW=F9$!3kp=lv+O&="F=7$$"3#RLL$))*yo">F9$!3nR#Q"44)yt"F=7$$"3_L$eR666*>F9$!3a_R`i7!>T#F=7$$"3;nT5g&GZ1#F9$!3IfK(fY$=*=$F=7$$"3Y++]Z`PK@F9$!3ijuD,e)*)*RF=7$$"3"pm"z*>1*4AF9$!3ygk-D"o'R]F=7$$"3[LLL=2DzAF9$!3]i,B?oJsgF=7$$"33+vVQk=`BF9$!3ChmL()4FzsF=7$$"3I+DccB&RU#F9$!3^wR(>dzo`)F=7$$"3++++++++DF9F47S7$$!3++++++++]F=$!3+++++++]PF97$$!3MLLLe%G?y%F=$!3%*****\P&3Yo$F97$$!3OmmT&esBf%F=$!3"***\iv<rFOF97$$!3KLL$3s%3zVF=$!31++D;asjNF97$$!33LL$e/$QkTF=$!39++v8\J*\$F97$$!3!pm;/"=q]RF=$!3=+]7V0@NMF97$$!3SLL3_>f_PF=$!3I+]i&exdP$F97$$!3))***\(o1YZNF=$!3u**\i+#QUJ$F97$$!3]LL3-OJNLF=$!3++]i!3%f]KF97$$!3C++v$*o%Q7$F=$!3M+]7oS:(=$F97$$!3ammm"RFj!HF=$!32++]<#)*=7$F97$$!3JLL$e4OZr#F=$!3))***\(G3UkIF97$$!3=+++v'\!*\#F=$!31++]-\r**HF97$$!33+++DwZ#G#F=$!3"*****\(GVZ$HF97$$!3-+++D.xt?F=$!31++](4J@(GF97$$!3OLL3-TC%)=F=$!3!***\iIKF:GF97$$!3!omm;4z)e;F=$!3+++]FPmZFF97$$!3+nmmm`'zY"F=$!3)*******4'*Q!p#F97$$!3E++v=t)eC"F=$!3-+]i&>mPi#F97$$!39nmm;1J\5F=$!33+++&=$zkDF97$$!3&y***\(=[jL)Fdp$!3;+]iX/4+DF97$$!3M****\iXg#G'Fdp$!39+](o8y%QCF97$$!3WlmmT&Q(RTFdp$!3!****\i:#>uBF97$$!3;nm;/'=><#Fdp$!38+]7ev::BF97$$!3vDMLLe*e$\Faw$!3/++vo2[^AF97$$"3[em;zRQb@Fdp$!3-+]i![Q`=#F97$$"3'[***\(=>Y2%Fdp$!30+]PC9wF@F97$$"3Qhmm"zXu9'Fdp$!3Q++DEmdl?F97$$"3]'******\y))G)Fdp$!3))*****\kL8+#F97$$"3'*)***\i_QQ5F=$!3J++D@W[Q>F97$$"3@***\7y%3T7F=$!3C+]ilXnx=F97$$"35****\P![hY"F=$!3F++v)eb,"=F97$$"3kKLL$Qx$o;F=$!3A+++&y'[\<F97$$"3!)*****\P+V)=F=$!3%*****\())4Zo"F97$$"3?mm"zpe*z?F=$!39+]i!R7gi"F97$$"3%)*****\#\'QH#F=$!31++]A0%=c"F97$$"3GKLe9S8&\#F=$!3?+]i&zf9]"F97$$"3R***\i?=bq#F=$!3=+]7QXMQ9F97$$"3"HLL$3s?6HF=$!37++]Pyjw8F97$$"3a***\7`Wl7$F=$!39+]iSm.78F97$$"3#pmmm'*RRL$F=$!3#)******4!=)\7F97$$"3Qmm;a<.YNF=$!3'****\PZ!>'="F97$$"3=LLe9tOcPF=$!30+]i0)*3B6F97$$"3u******\Qk\RF=$!33+++Xo5l5F97$$"3CLL$3dg6<%F=$!39****\(G=l)**F=7$$"3ImmmmxGpVF=$!3+++++n8#R*F=7$$"3A++D"oK0e%F=$!3G***\i&>Se()F=7$$"3A++v=5s#y%F=$!3M***\P%p$=:)F=7$$"3++++++++]F=$!3++++++++vF=7S7$$F6F6$!"#F67$$"3emmm;arz@Fdp$!3ymmm"p0k&>F97$$"3[LL$e9ui2%Fdp$!3FLL3<XZ=>F97$$"3nmmm"z_"4iFdp$!3cmm;Wp"e(=F97$$"3[mmmT&phN)Fdp$!3hmm;4m(G$=F97$$"3CLLe*=)H\5F=$!3QLL3i.9!z"F97$$"3gmm"z/3uC"F=$!3emmT!R=0v"F97$$"3%)***\7LRDX"F=$!3)****\P8#\4<F97$$"3]mm"zR'ok;F=$!3!om;/siqm"F97$$"3w***\i5`h(=F=$!3%****\(y$pZi"F97$$"3WLLL3En$4#F=$!3ILLLyaE"e"F97$$"3qmm;/RE&G#F=$!3mmm;>s%Ha"F97$$"3")*****\K]4]#F=$!3/+++N*4)*\"F97$$"3$******\PAvr#F=$!3-+++Db\c9F97$$"3)******\nHi#HF=$!3*)*****\1aZT"F97$$"3jmm"z*ev:JF=$!3ommT?)[oP"F97$$"3?LLL347TLF=$!3ZLLL=exJ8F97$$"3,LLLLY.KNF=$!3SLLLtIf$H"F97$$"3w***\7o7Tv$F=$!3;++vju<\7F97$$"3'GLLLQ*o]RF=$!3aLLLB@')47F97$$"3A++D"=lj;%F=$!3'****\P'psm6F97$$"31++vV&R<P%F=$!35++D"4_c7"F97$$"3WLL$e9Ege%F=$!3ULL$3x%z#3"F97$$"3GLLeR"3Gy%F=$!3MLL3s$QM/"F97$$"3cmm;/T1&*\F=$!3pmm;zr)4+"F97$$"3&em;zRQb@&F=$!3Iom;/K#*o&*F=7$$"3\***\(=>Y2aF=$!3-,+]ih2&=*F=7$$"39mm;zXu9cF=$!3snmmT3^q()F=7$$"3l******\y))GeF=$!3q++++VAU$)F=7$$"3'*)***\i_QQgF=$!33-++v%HK#zF=7$$"3@***\7y%3TiF=$!3d,+]P/$y^(F=7$$"35****\P![hY'F=$!3y,++DRqnqF=7$$"3kKLL$Qx$omF=$!3uMLLL_CjmF=7$$"3!)*****\P+V)oF=$!3R+++]#*RJiF=7$$"3?mm"zpe*zqF=$!3enm;/E3SeF=7$$"3%)*****\#\'QH(F=$!3M+++],F7aF=7$$"3GKLe9S8&\(F=$!3VNL$3(>t4]F=7$$"3R***\i?=bq(F=$!3?,+](ej*)e%F=7$$"3"HLL$3s?6zF=$!3=MLL$e&exTF=7$$"3a***\7`Wl7)F=$!3#4++v$4"pu$F=7$$"3#pmmm'*RRL)F=$!3;mmmm+7KLF=7$$"3Qmm;a<.Y&)F=$!3Bnmm"\Oz!HF=7$$"3=LLe9tOc()F=$!3mLL$3Pls[#F=7$$"3u******\Qk\*)F=$!3`++++Br+@F=7$$"3CLL$3dg6<*F=$!3]LLLe)ywl"F=7$$"3ImmmmxGp$*F=$!3UnmmmWUh7F=7$$"3A++D"oK0e*F=$!3E&****\PY$*Q)Fdp7$$"3A++v=5s#y*F=$!3i&****\izbM%Fdp7$$"""F6F^[m7SFgjl7$$"35mmmT:(z@&F=$!3!RLL$e%G?G(F=7$$"3jLLe9ui2aF=$!3OmmT&esB4(F=7$$"3Anm;z_"4i&F=$!3yKL$3s%3zoF=7$$"3$pmmT&phNeF=$!33LL$e/$QkmF=7$$"35LLe*=)H\gF=$!3!pm;/"=q]kF=7$$"3;nm"z/3uC'F=$!3'GL$3_>f_iF=7$$"37++DJ$RDX'F=$!3))***\(o1YZgF=7$$"3'fm;zR'okmF=$!30ML3-OJNeF=7$$"3I++D1J:woF=$!3p***\P*o%Qi&F=7$$"3WLLL3En$4(F=$!3ammm"RFjS&F=7$$"3qmm;/RE&G(F=$!3JLL$e4OZ@&F=7$$"3")*****\K]4](F=$!3=+++v'\!**\F=7$$"3$******\PAvr(F=$!33+++DwZ#y%F=7$$"3`+++v'Hi#zF=$!3[*****\KqPd%F=7$$"3jmm"z*ev:")F=$!3OLL3-TC%Q%F=7$$"3kKLL347T$)F=$!3Onmm"4z)eTF=7$$"3,LLLLY.K&)F=$!3+nmmm`'z'RF=7$$"3?***\7o7Tv)F=$!3!3+](=t)eu$F=7$$"3IKLL$Q*o]*)F=$!3qnmm;1J\NF=7$$"3A++D"=lj;*F=$!3y***\(=[jLLF=7$$"3]***\PaR<P*F=$!3\++Dc/EGJF=7$$"3!HLLe9Ege*F=$!35nm;aQ(R"HF=7$$"3GLLeR"3Gy*F=$!3smmTg=><FF=7$$"3cmm;/T1&***F=$!3VLL$e*e$\]#F=7$$"3em;zRQb@5F9$!3;ML3-;Y%G#F=7$$"3%)**\(=>Y2/"F9$!3i,+D"3QD4#F=7$$"3imm"zXu91"F9$!3'QLL3Ub_)=F=7$$"3'******\y))G3"F9$!3O+++]@6r;F=7$$"3!****\i_QQ5"F9$!3/,+]PZhh9F=7$$"3#***\7y%3T7"F9$!3y++v=_"*e7F=7$$"3#****\P![hY6F9$!3*3++D'>&Q."F=7$$"3ELLLQx$o;"F9$!3ptmmmhA;$)Fdp7$$"3')****\P+V)="F9$!318++]i*p:'Fdp7$$"3im;zpe*z?"F9$!3!zLL3-8/?%Fdp7$$"3)*****\#\'QH7F9$!3o,++]2Nh?Fdp7$$"37L$e9S8&\7F9$!3oF)omT&)f'[Faw7$$"3%***\i?=bq7F9$"3#R***\i?=b?Fdp7$$"3GLL$3s?6H"F9$"33HLL$3s?6%Fdp7$$"3&***\7`Wl78F9$"3Q&***\7`WliFdp7$$"3emmm'*RRL8F9$"36emmm'*RR$)Fdp7$$"3_mmTvJga8F9$"3Glm;a<.Y5F=7$$"3KL$e9tOcP"F9$"3=LLe9tOc7F=7$$"3'******\Qk\R"F9$"3u******\Qk\9F=7$$"3@LL3dg6<9F9$"39KL$3dg6n"F=7$$"3_mmmw(GpV"F9$"3=lmmmxGp=F=7$$"3-+]7oK0e9F9$"3A++D"oK03#F=7$$"3-+](=5s#y9F9$"3A++v=5s#G#F=7$$"3++++++++:F9$Fe[lF=7SF\jm7$$"3hmm;arz@5F9F^[m7$$"3OL$e9ui2/"F9F^[m7$$"3smm"z_"4i5F9F^[m7$$"3qmmT&phN3"F9F^[m7$$"3UL$e*=)H\5"F9F^[m7$$"3sm;z/3uC6F9F^[m7$$"3-+]7LRDX6F9F^[m7$$"3em;zR'ok;"F9F^[m7$$"3-+]i5`h(="F9F^[m7$$"3YLL$3En$47F9F^[m7$$"3cmmT!RE&G7F9F^[m7$$"3)*****\K]4]7F9F^[m7$$"3))****\PAvr7F9F^[m7$$"3/++]nHi#H"F9F^[m7$$"3bm;z*ev:J"F9F^[m7$$"3ELL$347TL"F9F^[m7$$"3=LLLjM?`8F9F^[m7$$"3#***\7o7Tv8F9F^[m7$$"3ALLLQ*o]R"F9F^[m7$$"3-+]7=lj;9F9F^[m7$$"3&***\PaR<P9F9F^[m7$$"3GLLe9Ege9F9F^[m7$$"3WL$eR"3Gy9F9F^[m7$$"3mmmT5k]*\"F9F^[m7$$"3em;zRQb@:F9F^[m7$$"3%)**\(=>Y2a"F9F^[m7$$"3imm"zXu9c"F9F^[m7$$"3'******\y))Ge"F9F^[m7$$"3!****\i_QQg"F9F^[m7$$"3#***\7y%3Ti"F9F^[m7$$"3#****\P![hY;F9F^[m7$$"3ELLLQx$om"F9F^[m7$$"3')****\P+V)o"F9F^[m7$$"3im;zpe*zq"F9F^[m7$$"3)*****\#\'QH<F9F^[m7$$"37L$e9S8&\<F9F^[m7$$"3%***\i?=bq<F9F^[m7$$"3GLL$3s?6z"F9F^[m7$$"3&***\7`Wl7=F9F^[m7$$"3emmm'*RRL=F9F^[m7$$"3_mmTvJga=F9F^[m7$$"3KL$e9tOc(=F9F^[m7$$"3'******\Qk\*=F9F^[m7$$"3@LL3dg6<>F9F^[m7$$"3_mmmw(Gp$>F9F^[m7$$"3-+]7oK0e>F9F^[m7$$"3-+](=5s#y>F9F^[m7$$""#F6F^[m-%&COLORG62%$RGBG$F6F5FdboFdboFdboFdbo$F-F5FeboFdboFdboFdboFeboFdboFeboFdboFebo-%*THICKNESSG6#F_bo-%*GRIDSTYLEG6#%,RECTANGULARG-Fabo6#%%NONEG-%%VIEWG6$;$!#5F5$"#DF5;$!1)***********zj!#:$"#QF`[m
<Text-field style="Heading 1" layout="Heading 1"><Font foreground="[51,153,0]">Horizontal and Vertical Asymptotes (Review)</Font></Text-field>
The presence of both horizontal and vertical asymptotes are verified by calculating limits.
<Text-field style="Text" foreground="[0,0,128]" bold="true" size="18" layout="Heading 1"><Font bold="true" size="18" foreground="[0,0,128]">Exercises to submit</Font></Text-field>
When you and your partner/ team have absorbed the above material, proceed to the homework questions available via your course page.
<Text-field style="Heading 4" layout="Heading 4"></Text-field>
Written by C. Wyels, Fall '06.