Geometric application: arc length Problem: Find the length s of the arc defined by the curve y=f(x) from a to b. Solution: Use differential element method,

Slides:

Advertisements

Similar presentations

Aula 5 Mecânica dos Fluidos 2-Estática do fluido.

Advertisements

7.1 Areas Between Curves To find the area: divide the area into n strips of equal width approximate the ith strip by a rectangle with base Δx and height.

Section 6.1 Volumes By Slicing and Rotation About an Axis

15 MULTIPLE INTEGRALS.

Chapter 15 – Multiple Integrals 15.5 Applications of Double Integrals 1 Objectives:  Understand the physical applications of double integrals Dr. Erickson.

Fluid Statics Pascal’s Law tells us that “Pressure at any point in a fluid is the same in all directions”. This means that any object submerged in a fluid.

FURTHER APPLICATIONS OF INTEGRATION

Static Surface Forces hinge water ? 8 m 4 m . Static Surface Forces ä Forces on plane areas ä Forces on curved surfaces ä Buoyant force ä Stability of.

Hinge Statics ? Surface Forces.

Static Surface Forces hinge water ? 8 m 4 m . Static Surface Forces ä Forces on plane areas ä Forces on curved surfaces ä Buoyant force ä Stability submerged.

Static Surface Forces hinge 8 m water ? 4 m.

FURTHER APPLICATIONS OF INTEGRATION

Monroe L. Weber-Shirk S chool of Civil and Environmental Engineeringhinge ? Statics Surface Forces 

Chapter 5 Applications of the Integral. 5.1 Area of a Plane Region Definite integral from a to b is the area contained between f(x) and the x-axis on.

Applications of Integration

Chapter 8 – Further Applications of Integration

It is represented by CG. or simply G or C.

Hinge Statics ? Surface Forces.

The graph: Similarly, parisa yazdjerdi.

Applications of Double Integrals

6.4 Arc Length. Length of a Curve in the Plane If y=f(x) s a continuous first derivative on [a,b], the length of the curve from a to b is.

Center of Mass and Moments of Inertia

Engineering Mechanics: Statics

Engineering Mechanics: Statics

Chapter 6 Applications of Integration 机动目录上页下页返回结束 6.1 Area Between Curves 6.2 Volume 6.3 Volume by Cylindrical Shell 6.5 Average Value of a Function.

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

Summary of area formula

9.3 Composite Bodies Consists of a series of connected “simpler” shaped bodies, which may be rectangular, triangular or semicircular A body can be sectioned.

Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.

APPLICATIONS OF DOUBLE INTEGRALS

Copyright © 2010 Pearson Education South Asia Pte Ltd

Copyright © Cengage Learning. All rights reserved. 8 Further Applications of Integration.

Centroids Lesson Centroid Center of mass for a system  The point where all the mass seems to be concentrated  If the mass is of constant density.

The center of gravity of a rigid body is the point G where a single force W, called the weight of the body, can be applied to represent the effect of the.

Chapter 7. Applications of the Definite integral in Geometry, Science, and Engineering By Jiwoo Lee Edited by Wonhee Lee.

Centroids and Centers of Gravity

7.4 Length of a Plane Curve y=f(x) is a smooth curve on [a, b] if f ’ is continuous on [a, b].

The Area Between Two Curves Lesson 6.1. When f(x) < 0 Consider taking the definite integral for the function shown below. The integral gives a ___________.

Water Pressure and Pressure Force (Revision) The Islamic University of Gaza Faculty of Engineering Civil Engineering Department Hydraulics - ECIV 3322.

ESSENTIAL CALCULUS CH07 Applications of integration.

Chapter 7-Applications of the Integral Calculus, 2ed, by Blank & Krantz, Copyright 2011 by John Wiley & Sons, Inc, All Rights Reserved.

9.6 Fluid Pressure According to Pascal’s law, a fluid at rest creates a pressure ρ at a point that is the same in all directions Magnitude of ρ measured.

Abj : Pressure, Pressure Force, and Fluid Motion Without Flow [Q1] 1.Area as A Vector  Component of Area Vector – Projected Area  Net Area Vector.

Moments, Center of Mass, Centroids Lesson 7.6. Mass Definition: mass is a measure of a body's resistance to changes in motion  It is independent of a.

Section 17.2 Line Integrals.

Copyright © Cengage Learning. All rights reserved. 8 Further Applications of Integration.

Volume: The Shell Method

FURTHER APPLICATIONS OF INTEGRATION 8. To work, our strategy is:  Break up the physical quantity into small parts.  Approximate each small part.  Add.

Applications of Integration 7 Copyright © Cengage Learning. All rights reserved.

8.3 Applications to Physics and Engineering In this section, we will discuss only one application of integral calculus to physics and engineering and this.

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

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.

Copyright © Cengage Learning. All rights reserved. 16 Vector Calculus.

Quick Review & Centers of Mass Chapter 8.3 March 13, 2007.

STROUD Worked examples and exercises are in the text Programme 20: Integration applications 2 INTEGRATION APPLICATIONS 2 PROGRAMME 20.

Chapter Area between Two Curves 7.2 Volumes by Slicing; Disks and Washers 7.3 Volumes by Cylindrical Shells 7.4 Length of a Plane Curve 7.5 Area.

Copyright © Cengage Learning. All rights reserved. 8.2 Area of a Surface of Revolution.

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.

Parametric equations Parametric equation: x and y expressed in terms of a parameter t, for example, A curve can be described by parametric equations x=x(t),

8.3 – Applications to Physics and Engineering

CHAPTER 9 Moments of Inertia.

ENGINEERING MECHANICS

Copyright © Cengage Learning. All rights reserved.

Centers of Mass Section 7.6.

Center of Mass, Center of Gravity, Centroids

INTEGRATION APPLICATIONS 2

7 Applications of Integration

Area of a Surface of Revolution

Presentation transcript:

Geometric application: arc length Problem: Find the length s of the arc defined by the curve y=f(x) from a to b. Solution: Use differential element method, take any element [x,x+dx], the length of the sub-arc corresponding to [x,x+dx] is: Therefore the total arc length is

Arc length formula If a curve has the equation x=g(y), then the length of the arc corresponding is Ex. Find the length of the arc of the parabola from (0,0) to (1,1). Sol.

Differential of arc length function A smooth curve is defined by y=f(x) and let s(x) be the length of the arc corresponding to the part from a to x. Then s(x) is called the arc length function, and we have formula The differential of arc length is

Geometric application: surface area A surface of revolution is generated by rotating a planar curve about a line. Problem: find the area of the surface obtained by rotating the curve about the x-axis.

Surface area formula Use differential element method, take an element [x,x+dx], the small surface is approximately a portion of a circular cone, thus its surface area is and therefore the total surface area is

Surface area formula If the curve is given by and rotate the curve about y-axis, then the surface area formula is Ex. The curve about x-axis, find the surface area. Sol.

Surface area formula If the curve is given by and rotate it about x-axis, the surface area formula is If the curve is and rotate about y-axis, the formula is

Example Ex. Find the area of the surface generated by rotating the curve segment from (1,1) to (2,4), about the y-axis. Sol I. Sol II.

Physical application: hydrostatic pressure Background: when an object is submerged in a fluid, the fluid will exert a force upon the object. The hydrostatic pressure is defined to be the force per unit area. Suppose the object is a thin horizontal plate. Its area is A and is submerged into depth d of a fluid with density Then we have By the principle of fluid pressure, at any point in a liquid the pressure is the same in all directions, we have

Hydrostatic force Ex. A cylindrical drum with radius 3m is submerged in water 10m deep. Find the hydrostatic force on one end of it. Sol. Use differential element method. First build up the coordinate frame with origin placed at the center of the drum. Take any infinitesimal element [x,x+dx], the pressure on this part is and the force is Therefore the total force is

Moments and centers of mass Center of mass: a point on which a thin plate balances horizontally A system of two masses and which lie at and respectively, the center of mass of the system is and are called the moments of the masses and (with respect to the origin) respectively.

Moment and center of mass A system of n particles located at the points on the x-axis, then is the center of mass of the system, is the total mass of the system, and the sum of individual moments is called the moments of the system about the origin.

Moment and center of mass A system of n particles located at the points in the xy-plane, then we define the moment of the system about the y-axis to be and the moment of the system about the x-axis as the coordinates of the center of mass of the system where is the total mass.

Moment and center of mass Consider a flat plate (called a lamina) with uniform density that occupies a region R of the plane. Center of mass is called the centroid The symmetry principle says that if R is symmetric about a line l, then the centroid of R lies on l. The moments are defined so that if the entire mass of a region is concentrated at the center of mass, then its moments remain unchanged. The moment of the union of two nonoverlapping regions is the sum of the moments of the individual regions.

Moment of a planar region Suppose the region R lies between the lines x=a and x=b, above the x-axis and below the curve y=f (x). Use differential element method: the moment of the subregion corresponding to [x,x+dx], about y-axis, is So the moment of R about y-axis is similarly, the moment of R about x-axis is

Center of mass of a planar region The center of mass of R is defined by the total mass is so the coordinates of the centroid are

Example Ex. Find the centroid of the region bounded by the curves y=cosx, y=0, x=0, and Sol.

Center of mass of a planar region Suppose now the region R lies between the lines x=a and x=b, above the curve y=g(x) and below the curve y=f (x) where The coordinates of the centroid are

Example Ex. Find the centroid of the region bounded by the line y=x and Sol.

Homework 20 Section 7.8: 25, 37, 40, 54, 55, 56, 58, 77 Section 8.1: 20, 37