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8.3 Relative Rates of Growth

8.3 Relative Rates of Growth. At 64 inches, the y-value would be at the edge of the known universe! (13 billion light-years). The function grows very fast. We could graph it on the chalkboard:. If x is 3 inches, y is about 20 inches:.

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8.3 Relative Rates of Growth

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  1. 8.3 Relative Rates of Growth

  2. At 64 inches, the y-value would be at the edge of the known universe! (13 billion light-years) 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!

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

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

  5. Please temporarily suspend your common sense. WARNING WARNING WARNING

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

  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. Definitionf 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. Order and Oh-Notation

  11. Definitionf 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 for x sufficiently large We write and say “f is big-oh of g.” Saying is another way to say that f grows no faster thang. Order and Oh-Notation p

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