Presentation is loading. Please wait.

Presentation is loading. Please wait.

Using Areas to Approximate to Sums of Series In the previous examples it was shown that an area can be represented by the sum of a series. Conversely the.

Published byCuthbert Casey Modified over 9 years ago

Similar presentations

Presentation on theme: "Using Areas to Approximate to Sums of Series In the previous examples it was shown that an area can be represented by the sum of a series. Conversely the."— Presentation transcript:

1 Using Areas to Approximate to Sums of Series In the previous examples it was shown that an area can be represented by the sum of a series. Conversely the sum of a series can be represented by an area.

2 Find lower and upper bounds for the sum of i.e

3 1234 n y = Represent the series by a set of rectangles, and approximate the area of these rectangles by the area under a curve. Rectangle 1 has an area of 1 x  1 =  1 Rectangle 2 has an area of 1 x  2 =  2 Rectangle n has an area of 1 x  n =  n n–1 n n+1 1 2

4 n–1 n 1234 n y = n+1 Represent the series by a set of rectangles, and approximate the area of these rectangles by the area under a curve. Hence the sum of the rectangle areas = 1 2

5 n–1 n 1234 n y = n+1 Represent the series by a set of rectangles, and approximate the area of these rectangles by the area under a curve. The area under y = from x = 1 to x = n+1 is too large 1 2

6 n–1 n 1234 n y = n+1 Represent the series by a set of rectangles, and approximate the area of these rectangles by the area under a curve. 1 2 So from eqn (1)

7 n–1 n 1234 n y = n+1 To obtain a lower bound, use the same rectangles translated 1 unit to the left. 1 2 but the x limits will be from 0 to n. Each rectangle still has a width of 1 and a height of So the sum of the areas of the rectangles still represents the sum of the series.

8 n–1 n 1234 n y = n+1 To obtain a lower bound, use the same rectangles translated 1 unit to the left. 1 2 The area under y = from x = 0 to x = n is too small

9 n–1 n 1234 n y = n+1 To obtain a lower bound, use the same rectangles translated 1 unit to the left. 12 So

10 Use the graph of y = To find upper and lower bounds for the sum of the series  +  +  +  … You do this one! n–1 nn+1 1 2 Lower Bound

11 Use the graph of y = To find upper and lower bounds for the sum of the series  +  +  +  … You do this one! n–1n 1 2 Upper Bound

12 Use the graph of y = x 2 To find upper and lower bounds for the sum of the series 1 2 +2 2 +3 2 +4 2 …10 2 You do this one!

13 Use the graph of y = x 2 To find upper and lower bounds for the sum of the series 1 2 +2 2 +3 2 +4 2 …10 2 You do this one! Upper Bound

14 Use the graph of y = x 2 To find upper and lower bounds for the sum of the series 1 2 +2 2 +3 2 +4 2 …10 2 You do this one! Lower Bound

Download ppt "Using Areas to Approximate to Sums of Series In the previous examples it was shown that an area can be represented by the sum of a series. Conversely the."

Similar presentations

Area Under a Curve (Linear). Find the area bounded by the x-axis, y = x and x =1. 1. Divide the x-axis from 0 to 1 into n equal parts. 2. Subdividing.

Area Under a Curve (Linear). Find the area bounded by the x-axis, y = x and x =1. 1. Divide the x-axis from 0 to 1 into n equal parts. 2. Subdividing.
Area Under A Curve And Writing a Riemann’s Sum

Area Under A Curve And Writing a Riemann’s Sum
A Riemann sum is a method for approximating the total area underneath a curve on a graph. This method is also known as taking an integral. There are 3.

A Riemann sum is a method for approximating the total area underneath a curve on a graph. This method is also known as taking an integral. There are 3.
5/16/2015 Perkins AP Calculus AB Day 5 Section 4.2.

5/16/2015 Perkins AP Calculus AB Day 5 Section 4.2.
Applying the well known formula:

Applying the well known formula:
The Definite Integral. In the previous section, we approximated area using rectangles with specific widths. If we could fit thousands of “partitions”

The Definite Integral. In the previous section, we approximated area using rectangles with specific widths. If we could fit thousands of “partitions”
INTEGRALS 5. 5.1 Areas and Distances INTEGRALS In this section, we will learn that: We get the same special type of limit in trying to find the area under.

INTEGRALS Areas and Distances INTEGRALS In this section, we will learn that: We get the same special type of limit in trying to find the area under.
Area Between Two Curves

Area Between Two Curves
1 Example 2 Estimate by the six Rectangle Rules using the regular partition P of the interval [0,  ] into 6 subintervals. Solution Observe that the function.

1 Example 2 Estimate by the six Rectangle Rules using the regular partition P of the interval [0,  ] into 6 subintervals. Solution Observe that the function.
Area Between Two Curves

Area Between Two Curves
5.1 Estimating with Finite Sums Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2002 Greenfield Village, Michigan.

5.1 Estimating with Finite Sums Greg Kelly, Hanford High School, Richland, WashingtonPhoto by Vickie Kelly, 2002 Greenfield Village, Michigan.
Every slope is a derivative. Velocity = slope of the tangent line to a position vs. time graph Acceleration = slope of the velocity vs. time graph How.

Every slope is a derivative. Velocity = slope of the tangent line to a position vs. time graph Acceleration = slope of the velocity vs. time graph How.
D MANCHE 2013. Finding the area under curves:  There are many mathematical applications which require finding the area under a curve.  The area “under”

D MANCHE Finding the area under curves:  There are many mathematical applications which require finding the area under a curve.  The area “under”
4.2 Area Under a Curve.

4.2 Area Under a Curve.
Aim: Finding Area Course: Calculus Do Now: Aim: An introduction to the 2 nd central Idea of Calculus.

Aim: Finding Area Course: Calculus Do Now: Aim: An introduction to the 2 nd central Idea of Calculus.
INTEGRALS 5. 5.1 Areas and Distances INTEGRALS In this section, we will learn that: We get the same special type of limit in trying to find the area under.

INTEGRALS Areas and Distances INTEGRALS In this section, we will learn that: We get the same special type of limit in trying to find the area under.
Section 7.2a Area between curves.

Section 7.2a Area between curves.
CHAPTER 4 SECTION 4.2 AREA.

CHAPTER 4 SECTION 4.2 AREA.
Section 15.3 Area and Definite Integral

Section 15.3 Area and Definite Integral
1 §12.4 The Definite Integral The student will learn about the area under a curve defining the definite integral.

1 §12.4 The Definite Integral The student will learn about the area under a curve defining the definite integral.

Similar presentations

Ads by Google