Adguary Calwile Laura Rogers Autrey~ 2nd Per. 3/14/11

Slides:

Advertisements

Similar presentations

Lesson Objectives By the end of this lesson you should be able to:

Advertisements

Numerical Integration

Adguary Calwile Laura Rogers Autrey~ 2nd Per. 3/14/11

Cameron Clary. Riemann Sums, the Trapezoidal Rule, and Simpson’s Rule are used to find the area of a certain region between or under curves that usually.

Section 8.5 Riemann Sums and the Definite Integral.

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.

Riemann Sums Jim Wang Mr. Brose Period 6. Approximate the Area under y = x² on [ 0,4 ] a)4 rectangles whose height is given using the left endpoint b)4.

Trapezoidal Approximation Objective: To relate the Riemann Sum approximation with rectangles to a Riemann Sum with trapezoids.

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.

NUMERICAL DIFFERENTIATION The derivative of f (x) at x 0 is: An approximation to this is: for small values of h. Forward Difference Formula.

Decimal Division You must learn the rules. Dividing a decimal by a whole number 1.2 ÷ 2 Divisor = 2 Dividend = 1.2 Step 1: move the decimal in the dividend.

Integration. Problem: An experiment has measured the number of particles entering a counter per unit time dN(t)/dt, as a function of time. The problem.

Numerical Integration

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

Chapter 7 – Techniques of Integration

Numerical Integration

Trapezoidal Approximation Objective: To find area using trapezoids.

An introduction to integration Thursday 22 nd September 2011 Newton Project.

Homework questions thus far??? Section 4.10? 5.1? 5.2?

1 Copyright © 2015, 2011 Pearson Education, Inc. Chapter 5 Integration.

Riemann Sums, Trapezoidal Rule, and Simpson’s Rule Haley Scruggs 1 st Period 3/7/11.

 The number of x-values is the same as the number of strips. SUMMARY where n is the number of strips.  The width, h, of each strip is given by ( but.

Definite Integrals Riemann Sums and Trapezoidal Rule.

5.1 Estimating with Finite Sums Greenfield Village, Michigan.

E.g. Use 4 strips with the mid-ordinate rule to estimate the value of Give the answer to 4 d.p. Solution: We need 4 corresponding y -values for x 1, x.

Section 7.6 – Numerical Integration. represents the area between the curve 3/x and the x-axis from x = 4 to x = 8.

1 Example 1 Estimate by the six Rectangle Rules using the regular partition P of the interval [0,1] into 4 subintervals. Solution This definite integral.

Estimating area under a curve

Section 7.6 – Numerical Integration. represents the area between the curve 3/x and the x-axis from x = 4 to x = 8.

Riemann Sums Lesson 14.2 Riemann Sums are used to approximate the area between a curve and the x-axis over an interval. Riemann sums divide the areas.

Riemann Sums and the Definite Integral. represents the area between the curve 3/x and the x-axis from x = 4 to x = 8.

Warm up 10/16 (glue in). Be seated before the bell rings DESK homework Warm-up (in your notes) Agenda : go over hw Finish Notes lesson 4.5 Start 4.6.

WS: Riemann Sums. TEST TOPICS: Area and Definite Integration Find area under a curve by the limit definition. Given a picture, set up an integral to calculate.

2/28/2016 Perkins AP Calculus AB Day 15 Section 4.6.

Integration – Overall Objectives  Integration as the inverse of differentiation  Definite and indefinite integrals  Area under the curve.

Definite Integral df. f continuous function on [a,b]. Divide [a,b] into n equal subintervals of width Let be a sample point. Then the definite integral.

Integrals NO CALCULATOR TEST Chapter 5. Riemann Sums 5.1.

Clicker Question 1 What is ? (Hint: u-sub) – A. ln(x – 2) + C – B. x – x 2 + C – C. x + ln(x – 2) + C – D. x + 2 ln(x – 2) + C – E. 1 / (x – 2) 2 + C.

Definite Integrals & Riemann Sums

5.2 – The Definite Integral. Introduction Recall from the last section: Compute an area Try to find the distance traveled by an object.

[5-4] Riemann Sums and the Definition of Definite Integral Yiwei Gong Cathy Shin.

7.2: Riemann Sums: Left & Right-hand Sums

Application of the Integral

NUMERICAL DIFFERENTIATION Forward Difference Formula

5.5 The Trapezoid Rule.

Lecture 19 – Numerical Integration

Use the Midpoint Rule to approximate the given integral with the specified value of n. Compare your result to the actual value and find the error in the.

Approximate Integration

Riemann Sums and the Definite Integral

Midpoint and Trapezoidal Rules

NUMERICAL INTEGRATION

Riemann Sum, Trapezoidal Rule, and Simpson’s Rule

5. 7a Numerical Integration. Trapezoidal sums

Approximating Definite Integrals. Left Hand Riemann Sums.

Approximating Definite Integrals. Left Hand Riemann Sums.

Section 3.2 – Calculating Areas; Riemann Sums

Integration & Area Under a Curve

Find an approximation to {image} Use a double Riemann sum with m = n = 2 and the sample point in the lower left corner to approximate the double integral,

If {image} find the Riemann sum with n = 5 correct to 3 decimal places, taking the sample points to be midpoints

Chapter 4 Integration.

Applications of Integration

Lesson 16 and 17 Area and Riemann Sums

5. 7a Numerical Integration. Trapezoidal sums

4.3 Day 1 Exit Ticket for Feedback

Section 3.2 – Calculating Areas; Riemann Sums

Arc Length … x y a b xi ... Pi P0 P1 Pn

Area Under a Curve Riemann Sums.

Chapter 5 Integration.

Jim Wang Mr. Brose Period 6

Presentation transcript:

Adguary Calwile Laura Rogers Autrey~ 2nd Per. 3/14/11 Finding the area under a curve: Riemann, Trapezoidal, and Simpson’s Rule Adguary Calwile Laura Rogers Autrey~ 2nd Per. 3/14/11

Introduction to area under a curve Before integration was developed, people found the area under curves by dividing the space beneath into rectangles, adding the area, and approximating the answer. As the number of rectangles, n, increases, so does the accuracy of the area approximation.

Introduction to area under a curve (cont.) There are three methods we can use to find the area under a curve: Riemann sums, the trapezoidal rule, and Simpson’s rule. For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Riemann Sums There are three types of Riemann Sums Right Riemann: Left Riemann: Midpoint Riemann:

Right Riemann- Overview Right Riemann places the right point of the rectangles along the curve to find the area. The equation that is used for the RIGHT RIEMANN ALWAYS begins with: And ends with Within the brackets!

Right Riemann- Example Remember: Right Only Given this problem below, what all do we need to know in order to find the area under the curve using Right Riemann? 4 partitions

Right Riemann- Example For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Right Riemann- Example

Right Riemann TRY ME! Volunteer:___________________ 4 Partitions

!Show All Your Work! n=4

Did You Get It Right? n=4

Left Riemann- Overview Left Riemann uses the left corners of rectangles and places them along the curve to find the area. The equation that is used for the LEFT RIEMANN ALWAYS begins with: And ends with Within the brackets!

Left Riemann- Example Remember: Left Only Given this problem below, what all do we need to know in order to find the area under the curve using Left Riemann? 4 partitions

Left Riemann- Example For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Left Riemann- Example

Volunteer:___________ Left Riemann- TRY ME! Volunteer:___________ 3 Partitions

!Show All Your Work! n=3

Did You Get My Answer? n=3

Midpoint Riemann- Overview Midpoint Riemann uses the midpoint of the rectangles and places them along the curve to find the area. The equation that is used for MIDPOINT RIEMANN ALWAYS begins with: And ends with Within the brackets!

Midpoint Riemann- Example Remember: Midpoint Only Given this problem below, what all do we need to know in order to find the area under the curve using Midpoint Riemann? 4 partitions

Midpoint Riemann- Example For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Midpoint Riemann- Example

Midpoint Riemann- TRY ME Volunteer:_________ 6 partitions

!Show Your Work! n=6

Correct??? n=6

Trapezoidal Rule Overview Trapezoidal Rule is a little more accurate that Riemann Sums because it uses trapezoids instead of rectangles. You have to know the same 3 things as Riemann but the equation that is used for TRAPEZOIDAL RULE ALWAYS begins with: and ends with Within the brackets with every“ f ” being multiplied by 2 EXCEPT for the first and last terms

Trapezoidal Rule- Example Remember: Trapezoidal Rule Only Given this problem below, what all do we need to know in order to find the area under the curve using Trapezoidal Rule? 4 partitions

Trapezoidal Example For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Trapezoidal Rule- Example

Trapezoidal Rule- TRY Me Volunteer:_____________ 4 Partitions

Trapezoidal Rule- TRY ME!! n=4

Was this your answer? n=4

Simpson’s Rule- Overview Simpson’s rule is the most accurate method of finding the area under a curve. It is better than the trapezoidal rule because instead of using straight lines to model the curve, it uses parabolic arches to approximate each part of the curve. The equation that is used for Simpson’s Rule ALWAYS begins with: And ends with Within the brackets with every “f” being multiplied by alternating coefficients of 4 and 2 EXCEPT the first and last terms. In Simpson’s Rule, n MUST be even.

Simpson’s Rule- Example Remember: Simpson’s Rule Only Given this problem below, what all do we need to know in order to find the area under the curve using Simpson’s Rule? 4 Partitions

Simpson’s Example For each method we must know: f(x)- the function of the curve n- the number of partitions or rectangles (a, b)- the boundaries on the x-axis between which we are finding the area

Simpson’s Rule- Example

Simpson’s Rule TRY ME! Volunteer:____________ 4 partitions

!Show Your Work! n=4

Check Your Answer!

Sources http://www.intmath.com/Integration © Laura Rogers, Adguary Calwile; 2011