14.4 Center of Mass Note: the equation for this surface is ρ= sinφ (in spherical coordinates)

Slides:

Advertisements

Similar presentations

15 MULTIPLE INTEGRALS.

Advertisements

2.2 Parallel and Perpendicular Lines and Circles Slopes and Parallel Lines 1. If two nonvertical lines are parallel, then they have the same slopes. 2.

9.3 Polar and Rectangular Coordinates. The following relationships exist between Polar Coordinates (r,  ) and Rectangular Coordinates (x, y): Polar vs.

Double Integrals Area/Surface Area Triple Integrals.

Polar Coordinates (MAT 170) Sections 6.3

Vectors and the Geometry of Space 9. 2 Announcement Wednesday September 24, Test Chapter 9 (mostly )

Spherical Coordinates

EXAMPLE 1 Write an equation of a circle Write the equation of the circle shown. The radius is 3 and the center is at the origin. x 2 + y 2 = r 2 x 2 +

10.6 Equations of Circles Advanced Geometry. What do you need to find the equation of a circle? Coordinates of the Center of the circle. Radius – Distance.

Applications of Double Integrals

Evaluate without integration: Don’t know.

POLAR COORDINATES (Ch )

14.3 Change of Variables, Polar Coordinates

Center of Mass and Moments of Inertia

Section 10.1 Polar Coordinates.

CHAPTER 13 Multiple Integrals Slide 2 © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 13.1DOUBLE INTEGRALS 13.2AREA,

Multiple Integration 14 Copyright © Cengage Learning. All rights reserved.

11.7 Cylindrical and Spherical Coordinates. The Cylindrical Coordinate System In a cylindrical coordinate system, a point P in space is represented by.

Copyright © Cengage Learning. All rights reserved.

APPLICATIONS OF DOUBLE INTEGRALS

Multiple Integrals 12.

Section 11.7 – Conics in Polar Coordinates If e 1, the conic is a hyperbola. The ratio of the distance from a fixed point (focus) to a point on the conic.

Vector Calculus CHAPTER 9.10~9.17. Ch9.10~9.17_2 Contents  9.10 Double Integrals 9.10 Double Integrals  9.11 Double Integrals in Polar Coordinates 9.11.

EXAMPLE 3 Write the standard equation of a circle The point (–5, 6) is on a circle with center (–1, 3). Write the standard equation of the circle. SOLUTION.

Sullivan Algebra and Trigonometry: Section 10.2 Objectives of this Section Graph and Identify Polar Equations by Converting to Rectangular Coordinates.

Chapter 14 Multiple Integration. Copyright © Houghton Mifflin Company. All rights reserved.14-2 Figure 14.1.

Warm – up #1 xy V( 0 2). Homework Log Wed 11/18 Lesson 4 – 1 Learning Objective: To graph circles Hw: #402 Pg. 220 #9, 10, 14 – 36 even,

SECTION 12.5 TRIPLE INTEGRALS.

The Circle. Examples (1) – (5) Determine the center and radius of the circle having the given equation. Identify four points of the circle.

9.6 Circles in the Coordinate Plane Date: ____________.

Chapter 17 Section 17.4 The Double Integral as the Limit of a Riemann Sum; Polar Coordinates.

Double Integrals in Polar Coordinates. Sometimes equations and regions are expressed more simply in polar rather than rectangular coordinates. Recall:

Centers of Mass. Particles of masses 6, 1, 3 are located at (-2,5), (3,3) & (3,-4) respectively. Find.

MAT 1236 Calculus III Section 15.5 Applications of Double Integrals

Applying Multiple Integrals Thm. Let ρ(x,y) be the density of a lamina corresponding to a plane region R. The mass of the lamina is.

Graphing Linear Equations 4.2 Objective 1 – Graph a linear equation using a table or a list of values Objective 2 – Graph horizontal or vertical lines.

Do Now Write the equation for the locus of points 5 units from the point (-5,6)

EXAMPLE 1 Write an equation of a circle Write the equation of the circle shown. SOLUTION The radius is 3 and the center is at the origin. x 2 + y 2 = r.

CHAPTER 13 Multiple Integrals Slide 2 © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 13.1DOUBLE INTEGRALS 13.2AREA,

Applications of Integration Copyright © Cengage Learning. All rights reserved.

Conic Sections Practice. Find the equation of the conic section using the given information.

Graphs and Applications of Linear Equations

Evaluate without integration:

Equations of Circles.

Polar Coordinates r Pole Polar axis.

Equations of Circles.

10.6 Equations of Circles Geometry.

Cylindrical – Polar Coordinates

A large tank is designed with ends in the shape of the region between the curves {image} and {image} , measured in feet. Find the hydrostatic force on.

Math 200 Week 9 - Wednesday Triple Integrals.

A large tank is designed with ends in the shape of the region between the curves {image} and {image} , measured in feet. Find the hydrostatic force on.

(4, 0) (0, 4) (2, 0) (-4, 0) (0, -4) (0, 2) None of these choices

Surface Integrals.

What is a radius of a circle? What about the diameter?

11.7 Circles in the Coordinate Plane

Equations of Circles.

Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.

11 Vectors and the Geometry of Space

Geometry Equations of Circles.

Parametric and Polar Curves

Centers of Mass Section 7.6.

Copyright © Cengage Learning. All rights reserved.

Solutions of Linear Functions

Circles in the Coordinate Plane

Equations of Circles Advanced Geometry.

15.7 Triple Integrals.

1.4 Parametric Equations Greg Kelly, Hanford High School, Richland, Washington.

Copyright © Cengage Learning. All rights reserved.

Presentation transcript:

14.4 Center of Mass Note: the equation for this surface is ρ= sinφ (in spherical coordinates)

Example 1 Find the mass of the triangular lamina with vertices (0,0), (0,3), and (2,3) given that the density at (x,y) is ρ(x,y) = 2x + y

Solution to Example 1

Example 2 (hint convert to polar coordinates) Find the mass of the lamina corresponding to the first-coordinate portion of the circle

Finding Center of Mass

Example 3 Find the center of mass of the lamina corresponding to the given parabolic region

Example 3 solution part 1

"A mathematician is a blind man in a dark room looking for a black cat which isn't there." -- Charles Darwin (quoted by Jaime Escalante in the film, STAND and DELIVER)

Figure 14.37

Figure 14.39

Figure 14.40