Geometric area integration of 1/x

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SUMMARY

The discussion focuses on demonstrating the geometric area under the curve of the function y = 1/x from x = 1 to x = 30, which is equal to ln(30) or approximately 3.4 area units. Participants explore the use of Riemann sums to approximate this area without a calculator, dividing the interval into N equal parts and calculating the area of rectangles formed under the curve. The conversation emphasizes that while geometric methods can provide approximations, integral calculus remains the preferred approach for exact calculations.

PREREQUISITES
  • Understanding of integral calculus concepts, specifically the natural logarithm function.
  • Familiarity with Riemann sums and their application in approximating areas under curves.
  • Basic knowledge of graphing functions, particularly y = 1/x.
  • Ability to manipulate algebraic expressions and summations.
NEXT STEPS
  • Study the properties of the natural logarithm and its relationship with the integral of 1/t.
  • Learn how to calculate Riemann sums for various functions and intervals.
  • Explore the concept of limits and their role in defining definite integrals.
  • Investigate alternative geometric interpretations of logarithmic functions.
USEFUL FOR

Mathematicians, calculus students, educators, and anyone interested in understanding the geometric interpretation of logarithmic functions and the application of Riemann sums in approximating areas under curves.

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given:
ln (x) = integral 1/t dt
from 1 to x
and x=30

Without a calculator and only a graph of y=1/x
How could you show that this geometric area under this curve (with any type of unit)
is equal to 3.4 area units, the ln (30)

not homework, I am looking for a tangible/physical example of above definition
 
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I'm not sure what you question is. If there were a purely geometric way to show that the area under y= 1/x, from x= 1 to x= 30, we wouldn't need integral calculus!

You could, of course, approximate it, using "Rieman sums". If we divide the x-axis, from x= 1 to x= 30, into N equal intervals, the right end of each interval is x= 1+ 29i/N with i from 1 to 30 and each interval has length 29/N. If we set up a rectangle with f(x)= f(1+ i/30)= 1/(1+ i/30)= 30/(i+30), then the area of each rectangle is (30/(i+ 30))(29/N). The area under the curve, then, is approximated by \sum 30(29)/(N(i+ 30). I suppose you could do that without using a calculator but I wouldn't want to! I will stick with calculus.
 

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