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Finding Limits Graphically and Numerically

Learn how to find average velocity graphically and numerically along with understanding distance traveled by an object, expression limits, observing limits, and formal definitions of limits. Plenty of examples and exercises provided for practice.

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Finding Limits Graphically and Numerically

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  1. Finding Limits Graphically and Numerically Lesson 2.2

  2. Average Velocity • Average velocity is the distance traveled divided by an elapsed time. A boy rolls down a hill on a skateboard. At time = 4 seconds, the boy has rolled 6 meters from the top of the hill. At time = 7 seconds, the boy has rolled to a distance of 30 meters. What is his average velocity?

  3. Distance Traveled by an Object • Given distance s(t) = 16t2 • We seek the velocity • or the rate of change of distance • The average velocity between 2 and t 2 t

  4. Average Velocity • Use calculator • Graph with window 0 < x < 5, 0 < y < 100 • Trace for x = 1, 3, 1.5, 1.9, 2.1, and then x = 2 • What happened? This is the average velocity function

  5. value to get close to variable to get close Expression Limit of the Function • Try entering in the expressionlimit(y1(x),x,2) • The function did not exist at x = 2 • but it approaches 64 as a limit

  6. a b Limit of the Function • Note: we can approach a limit from • left … right …both sides • Function may or may not exist at that point • At a • right hand limit, no left • function not defined • At b • left handed limit, no right • function defined

  7. Observing a Limit • Can be observed on a graph. ViewDemo

  8. Observing a Limit • Can be observed on a graph.

  9. Observing a Limit • Can be observed in a table • The limit is observed to be 64

  10. Non Existent Limits • Limits may not exist at a specific point for a function • Set • Consider the function as it approaches x = 0 • Try the tables with start at –0.03, dt = 0.01 • What results do you note?

  11. Non Existent Limits • Note that f(x) does NOT get closer to a particular value • it grows without bound • There is NO LIMIT • Try command oncalculator

  12. Non Existent Limits • f(x) grows without bound View Demo3

  13. Non Existent Limits View Demo 4

  14. Formal Definition of a Limit • The • For any ε (as close asyou want to get to L) • There exists a  (we can get as close as necessary to c ) • View Geogebra demo

  15. Formal Definition of a Limit • For any  (as close as you want to get to L) • There exists a  (we can get as close as necessary to cSuch that …

  16. Specified Epsilon, Required Delta

  17. Finding the Required  • Consider showing • |f(x) – L| = |2x – 7 – 1| = |2x – 8| <  • We seek a  such that when |x – 4| <  |2x – 8|<  for any  we choose • It can be seen that the  we need is

  18. Assignment • Lesson 2.2 • Page 76 • Exercises: 1 – 35 odd

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