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8.3 Relative Rates of Growth. The function grows very fast. We could graph it on the chalkboard: If x is 3 inches, y is about 20 inches: We have gone.

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Presentation on theme: "8.3 Relative Rates of Growth. The function grows very fast. We could graph it on the chalkboard: If x is 3 inches, y is about 20 inches: We have gone."— Presentation transcript:

1 8.3 Relative Rates of Growth

2 The function grows very fast. We could graph it on the chalkboard: If x is 3 inches, y is about 20 inches: We have gone less than half-way across the board horizontally, and already the y-value would reach the Andromeda Galaxy! At 64 inches, the y-value would be at the edge of the known universe! (13 billion light-years)

3 The function grows very slowly. If we graph it on the chalkboard it looks like this: We would have to move 2.6 miles to the right before the line moves a foot above the x-axis! 64 inches By the time we reach the edge of the universe again (13 billion light-years) the chalk line will only have reached 64 inches! The function increases everywhere, even though it increases extremely slowly.

4 Definitions: Faster, Slower, Same-rate Growth as Let f ( x ) and g ( x ) be positive for x sufficiently large. 1. f grows faster than g (and g grows slower than f ) as if or 2. f and g grow at the same rate as if

5 WARNING Please temporarily suspend your common sense.

6 According to this definition, does not grow faster than. Since this is a finite non-zero limit, the functions grow at the same rate! The book says that “ f grows faster than g ” means that for large x values, g is negligible compared to f. “Grows faster” is not the same as “has a steeper slope”!

7 Which grows faster, or ? This is indeterminate, so we apply L’Hôpital’s rule. Still indeterminate. grows faster than. We can confirm this graphically:

8 “Growing at the same rate” is transitive. In other words, if two functions grow at the same rate as a third function, then the first two functions grow at the same rate.

9 Example 4: Show that and grow at the same rate as. f and g grow at the same rate.

10 Order and Oh-Notation Definition f of Smaller Order than g Let f and g be positive for x sufficiently large. Then f is of smaller order than g as if We write and say “ f is little-oh of g.” Saying is another way to say that f grows slower than g.

11 Order and Oh-Notation Saying is another way to say that f grows no faster than g. Definition f of at Most the Order of g Let f and g be positive for x sufficiently large. Then f is of at most the order of g as if there is a positive integer M for which We write and say “ f is big-oh of g.” for x sufficiently large 

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