16.360 Lecture 13 Basic Laws of Vector Algebra Scalars: e.g. 2 gallons, $1,000, 35ºC Vectors: e.g. velocity: 35mph heading south 3N force toward center.

Slides:

Advertisements

Similar presentations

Differential Calculus (revisited):

Advertisements

Electric Flux Density, Gauss’s Law, and Divergence

Chapter 9: Vector Differential Calculus Vector Functions of One Variable -- a vector, each component of which is a function of the same variable.

VECTOR CALCULUS 1.10 GRADIENT OF A SCALAR 1.11 DIVERGENCE OF A VECTOR

ENTC 3331 RF Fundamentals Dr. Hugh Blanton ENTC 3331.

EEE 340Lecture Curl of a vector It is an axial vector whose magnitude is the maximum circulation of per unit area as the area tends to zero and.

EE3321 ELECTROMAGENTIC FIELD THEORY

General Physics (PHYS101)

EE2030: Electromagnetics (I)

Fundamentals of Applied Electromagnetics

Scalar-Vector Interaction for better Life …… P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Vector Analysis : Applications to.

2-7 Divergence of a Vector Field

Lecture 15 Today Transformations between coordinate systems 1.Cartesian to cylindrical transformations 2.Cartesian to spherical transformations.

Lecture 16 Today Gradient of a scalar field

Chapter 1 Vector analysis

1.1 Vector Algebra 1.2 Differential Calculus 1.3 Integral Calculus 1.4 Curvilinear Coordinate 1.5 The Dirac Delta Function 1.6 The Theory of Vector Fields.

Lecture 13 Today Basic Laws of Vector Algebra Scalars: e.g. 2 gallons, $1,000, 35ºC Vectors: e.g. velocity: 35mph heading south 3N force toward.

Lecture 1eee3401 Chapter 2. Vector Analysis 2-2, 2-3, Vector Algebra (pp ) Scalar: has only magnitude (time, mass, distance) A,B Vector: has both.

Lecture 14 Today Orthogonal coordinate systems 1.The Cartesian (rectangular) coordinate system 2.The cylindrical coordinate system 3.The spherical.

Lecture 18 Today Curl of a vector filed 1.Circulation 2.Definition of Curl operator in Cartesian Coordinate 3.Vector identities involving the curl.

Coordinate Systems.

Scalar and Vector Fields

1-1 Engineering Electromagnetics Chapter 1: Vector Analysis.

Fall Scalar Quantity (mass, speed, voltage, current and power) 1- Real number (one variable) 2- Complex number (two variables) Vector Algebra (velocity,

Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.

ELEN 3371 Electromagnetics Fall Lecture 2: Review of Vector Calculus Instructor: Dr. Gleb V. Tcheslavski Contact:

EMLAB 1 Chapter 1. Vector analysis. EMLAB 2 Mathematics -Glossary Scalar : a quantity defined by one number (eg. Temperature, mass, density, voltage,...

UNIVERSITI MALAYSIA PERLIS

February 18, 2011 Cross Product The cross product of two vectors says something about how perpendicular they are. Magnitude: –  is smaller angle between.

Review of Vector Analysis

1 Chapter 2 Vector Calculus 1.Elementary 2.Vector Product 3.Differentiation of Vectors 4.Integration of Vectors 5.Del Operator or Nabla (Symbol  ) 6.Polar.

1 April 14 Triple product 6.3 Triple products Triple scalar product: Chapter 6 Vector Analysis A B C + _.

7.1 Scalars and vectors Scalar: a quantity specified by its magnitude, for example: temperature, time, mass, and density Chapter 7 Vector algebra Vector:

EE 543 Theory and Principles of Remote Sensing

1.1 – 1.2 The Geometry and Algebra of Vectors.  Quantities that have magnitude but not direction are called scalars. Ex: Area, volume, temperature, time,

VECTOR CALCULUS. Vector Multiplication b sin   A = a  b Area of the parallelogram formed by a and b.

Review: Analysis vector. VECTOR ANALYSIS 1.1SCALARS AND VECTORS 1.2VECTOR COMPONENTS AND UNIT VECTOR 1.3VECTOR ALGEBRA 1.4POSITION AND DISTANCE VECTOR.

Applied Electricity and Magnetism

1. Determine vectors and scalars from these following quantities: weight, specific heat, density, volume, speed, calories, momentum, energy, distance.

Chapter 3 Vectors. Vectors – physical quantities having both magnitude and direction Vectors are labeled either a or Vector magnitude is labeled either.

Tuesday Sept 21st: Vector Calculus Derivatives of a scalar field: gradient, directional derivative, Laplacian Derivatives of a vector field: divergence,

Angular Velocity: Sect Overview only. For details, see text! Consider a particle moving on arbitrary path in space: –At a given instant, it can.

1 Vector Calculus. Copyright © 2007 Oxford University Press Elements of Electromagnetics Fourth Edition Sadiku2 Figure 3.1 Differential elements in the.

Electricity and Magnetism INEL 4151 Sandra Cruz-Pol, Ph. D. ECE UPRM Mayagüez, PR.

EMLAB 1 Chapter 1. Vector analysis. EMLAB 2 Mathematics -Glossary Scalar : a quantity defined by one number (eg. Temperature, mass, density, voltage,...

CALCULUS III CHAPTER 5: Orthogonal curvilinear coordinates

ENE 325 Electromagnetic Fields and Waves Lecture 2 Static Electric Fields and Electric Flux density.

University of Utah Introduction to Electromagnetics Lecture 14: Vectors and Coordinate Systems Dr. Cynthia Furse University of Utah Department of Electrical.

Chapter 2 Vector Calculus

Vector integration Linear integrals Vector area and surface integrals

Chapter 6 Vector Analysis

Lecture 19 Flux in Cartesian Coordinates.

ECE 305 Electromagnetic Theory

Soh Ping Jack, Azremi Abdullah Al-Hadi, Ruzelita Ngadiran

Force as gradient of potential energy

Chapter 3 Overview.

Outline Addition and subtraction of vectors Vector decomposition

Electromagnetics II.

EEE 161 Applied Electromagnetics

Review of Vector Calculus

Fields and Waves I Lecture 8 K. A. Connor Y. Maréchal

ENE/EIE 325 Electromagnetic Fields and Waves

Vector Calculus for Measurements in Thermofluids

EEE 161 Applied Electromagnetics

Chapter 6 Vector Analysis

Electricity and Magnetism I

Lecture 17 Today Divergence of a vector filed

Applied EM by Ulaby, Michielssen and Ravaioli

Fundamentals of Applied Electromagnetics

Lecture 16 Gradient in Cartesian Coordinates

Presentation transcript:

Lecture 13 Basic Laws of Vector Algebra Scalars: e.g. 2 gallons, $1,000, 35ºC Vectors: e.g. velocity: 35mph heading south 3N force toward center

Lecture 13 Cartesian coordinate system x y z A  

Lecture 13 Vector addition and subtraction C = B+A = A +B, |C| = |B+A| = |A| +|B|, A B C A B C head-to-tail rule parallelogram rule A B D D = A - B = -(B –A), A B D’ = (B-A)

Lecture 13 position and distance x y z A B D = A - B = -(B –A),

Lecture 13 Vector multiplication 1. simple product 2. scalar product (dot product)

Lecture 13 Properties of scalar product (dot product) a) commutative property b) Distributitve property

Lecture vector product (cross product) a) anticommutative property b) Distributitve property c)

Lecture vector product (cross product)

Lecture 13 Example vectors and angles In Cartesian coordinate, vector A is directed from origin to point P1(2,3,3), and vector B is directed from P1 to pint P2(1,-2,2). Find: (a) Vector A, its magnitude |A|, and unit vector a (b) the angle that A makes with the y-axis (c) Vector B (d) the angle between A and B (e) perpendicular distance from origin to vector B

Lecture Scalar and vector triple product a) scalar triple product b) vector triple product

Lecture 13 Example vector triple product

Lecture 14 Cartesian coordinate system x y z dl  

Lecture 14 Cartesian coordinate system x y z directions of area

Lecture 14 Cylindrical coordinate system z x y

Lecture 14 the differential areas and volume z x y

Lecture 14 Example: cylindrical area z x y

Lecture 14 Spherical coordinate system

Lecture 14 differential volume in Spherical coordinate system

Lecture 14 Examples (1) Find the area of the strip (2) A sphere of radius 2cm contains a volume charge density Find the total charge contained in the sphere

Lecture 15 Cartesian to cylindrical transformation

Lecture 15 Cartesian to cylindrical transformation

Lecture 15 Cartesian to cylindrical transformation

Lecture 15 Cartesian to Spherical transformation

Lecture 15 Cartesian to Spherical transformation

Lecture 15 Cartesian to Spherical transformation

Lecture 15 Distance between two points:

Lecture 16 Gradient in Cartesian Coordinates Gradient: differential change of a scalar The direction ofis along the maximum increase of T.

Lecture 16 Example of Gradient in Cartesian Coordinates Find the directional derivative ofalong the direction and evaluate it at (1, -1,2).

Lecture 16 Gradient operator in cylindrical Coordinates

Lecture 16 Gradient operator in cylindrical Coordinates z x y

Lecture 16 Gradient operator in Spherical Coordinates

Lecture 16 Properties of the Gradient operator

Lecture 17 Flux in Cartesian Coordinates

Lecture 17 Flux in Cartesian Coordinates

Lecture 17 Definition of divergence in Cartesian Coordinates

Lecture 17 Properties of divergence IfNo net flux on any closed surface. Divergence theorem

Lecture 17 Divergence in Cylindrical Coordinates z x y

Lecture 17 Divergence in Cylindrical Coordinates z x y

Lecture 17 Divergence in Spherical Coordinates

Lecture 17 Divergence in Spherical Coordinates

Lecture 17 Divergence in Spherical Coordinates

Lecture 18 Circulation of a Vector

Lecture 18 Circulation of a Vector

Lecture 18 Curl in Cartesian Coordinates

Lecture 18 Vector identities involving the curl Stokes’s theorem

Lecture 18 Curls in Rectangular, Cylindrical and Spherical Coordinates

Lecture 18 Laplacian Operator of a scalar

Lecture 18 Laplacian Operator of a vector