Finding Volumes.

Slides:

Advertisements

Similar presentations

Section Volumes by Slicing

Advertisements

Volumes by Slicing: Disks and Washers

Disks, Washers, and Cross Sections Review

Section Volumes by Slicing

Calculus, ET First Edition

6.2d4 Volume by Slicing. Revolve the area bound by the x-axis the curve f(x) = -(x - 1) and the x-axis.

More on Volumes & Average Function Value. Average On the last test (2), the average of the test was: FYI - there were 35 who scored a 9 or 10, which means.

Volumes – The Disk Method Lesson 7.2. Revolving a Function Consider a function f(x) on the interval [a, b] Now consider revolving that segment of curve.

7.1 Area Between 2 Curves Objective: To calculate the area between 2 curves. Type 1: The top to bottom curve does not change. a b f(x) g(x) *Vertical.

Volume: The Disk Method

Finding Volumes.

Volume of a Solid by Cross Section Section 5-9. Let be the region bounded by the graphs of x = y 2 and x=9. Find the volume of the solid that has as its.

6.2C Volumes by Slicing with Known Cross-Sections.

Section 7.2 Solids of Revolution. 1 st Day Solids with Known Cross Sections.

Cross Sections By: Meghan Grubb. What are cross sections? A cross sectional area results from the intersection of a solid with a plane, usually an x-y.

Volumes of Revolution Day 4 Volumes in Bases. The title is deceiving This section isn’t actually rotations – instead, there will be a shape whose base.

7.3 Day One: Volumes by Slicing. Volumes by slicing can be found by adding up each slice of the solid as the thickness of the slices gets smaller and.

Lesson 6-2a Volumes Known Cross-sectional Areas. Ice Breaker Find the volume of the region bounded by y = 1, y = x² and the y-axis revolved about the.

7.3.3 Volume by Cross-sectional Areas A.K.A. - Slicing.

Volume Section 7.3a. Recall a problem we did way back in Section 5.1… Estimate the volume of a solid sphere of radius 4. Each slice can be approximated.

Solids of Revolution Disk Method

Volume: The Disc Method

Let R be the region bounded by the curve y = e x/2, the y-axis and the line y = e. 1)Sketch the region R. Include points of intersection. 2) Find the.

Finding Volumes Chapter 6.2 February 22, In General: Vertical Cut:Horizontal Cut:

Volumes Lesson 6.2.

Volumes by Slicing 7.3 Solids of Revolution.

Volumes by Slicing. disk Find the Volume of revolution using the disk method washer Find the volume of revolution using the washer method shell Find the.

Volumes of Solids with Known Cross Sections

Volume Find the area of a random cross section, then integrate it.

Volume of Regions with cross- sections an off shoot of Disk MethodV =  b a (π r 2 ) dr Area of each cross section (circle) * If you know the cross.

SECTION 7-3-C Volumes of Known Cross - Sections. Recall: Perpendicular to x – axis Perpendicular to y – axis.

Secondary Math Two and Three-Dimensional Objects.

Calculus 6-R Unit 6 Applications of Integration Review Problems.

Drill: Find the area in the 4 th quadrant bounded by y=e x -5.6; Calculator is Allowed! 1) Sketch 2) Highlight 3) X Values 4) Integrate X=? X=0 X=1.723.

Section 7.3: Volume The Last One!!! Objective: Students will be able to… Find the volume of an object using one of the following methods: slicing, disk,

Applications of Integration

Volumes of solids with known cross sections

In this section, we will learn about: Using integration to find out

Finding Volumes Chapter 6.2 February 22, 2007.

Volumes – The Disk Method

Cross Sections Section 7.2.

Solids not generated by Revolution

Volume by Cross Sections

Volumes © James Taylor 2000 Dove Presentations.

Rotational Volumes Using Disks and Washers.

Review: Area betweens two curves

Volumes – The Disk Method

7 Applications of Integration

APPLICATIONS OF INTEGRATION

Find the volume of the solid obtained by rotating the region bounded by {image} and {image} about the x-axis. 1. {image}

6.4 Volumes by Cross Sections

Warmup 1) 2) 3).

Volume of Solids with Known Cross Sections

Volume by Cross-sectional Areas A.K.A. - Slicing

Applications Of The Definite Integral

7 Applications of Integration

Warm Up Find the volume of the following shapes (cubic inches)

Area & Volume Chapter 6.1 & 6.2 February 20, 2007.

Chapter 6 Cross Sectional Volume

6.1 Areas Between Curves To find the area:

Copyright © Cengage Learning. All rights reserved.

Cross Sections.

Section Volumes by Slicing

Section 7.2 Day 5 Cross Sections

Warm Up Find the volume of the following 3 dimensional shapes.

Presentation transcript:

Finding Volumes

In General: Vertical Cut: Horizontal Cut:

Find the area of the region bounded by Bounds? In terms of y: [-2,1] Points: (0,-2), (3,1) Right Function? Left Function? Area?

Volume & Definite Integrals We used definite integrals to find areas by slicing the region and adding up the areas of the slices. We will use definite integrals to compute volume in a similar way, by slicing the solid and adding up the volumes of the slices. For Example………………

Blobs in Space Volume of a blob: Cross sectional area at height h: A(h) Volume =

Example Solid with cross sectional area A(h) = 2h at height h. Stretches from h = 2 to h = 4. Find the volume.

Volumes: We will be given a “boundary” for the base of the shape which will be used to find a length. We will use that length to find the area of a figure generated from the slice . The dy or dx will be used to represent the thickness. The volumes from the slices will be added together to get the total volume of the figure.

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a square. [-1,1] Bounds? Top Function? Bottom Function? Length?

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a square. We use this length to find the area of the square. Length? Area? Volume?

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a square. What does this shape look like? Volume?

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a circle with diameter in the plane. Length? Area? Radius: Volume?

Using the half circle [0,1] as the base slices perpendicular to the x-axis are isosceles right triangles. Bounds? [0,1] Length? Area? Volume? Visual?

The base of the solid is the region between the curve and the interval [0,π] on the x-axis. The cross sections perpendicular to the x-axis are equilateral triangles with bases running from the x-axis to the curve. [0,π] Bounds? Top Function? Bottom Function? Length? Area of an equilateral triangle?

Area of an Equilateral Triangle? Area = (1/2)b*h

The base of the solid is the region between the curve and the interval [0,π] on the x-axis. The cross sections perpendicular to the x-axis are equilateral triangles with bases running from the x-axis to the curve. [0,π] Bounds? Top Function? Bottom Function? Length? Area of an equilateral triangle? Volume?

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a square with diagonal in the plane. We used this length to find the area of the square whose side was in the plane…. Length? Area with the length representing the diagonal?

Area of Square whose diagonal is in the plane?

Find the volume of the solid whose bottom face is the circle and every cross section perpendicular to the x-axis is a square with diagonal in the plane. Length of Diagonal? Length of Side? Area? Volume?