The scalar product of two vectors A and B is equal to the magnitude of vector A times the projection of B onto the direction of vector A. Consider two.

Slides:

Advertisements

Similar presentations

A two-dimensional vector v is determined by two points in the plane: an initial point P (also called the “tail” or basepoint) and a terminal point Q (also.

Advertisements

General Physics (PHYS101)

Lesson 6-3 The Scalar Product AP Physics C. 6 – 3 The scalar product, or dot product, is a mathematical operation used to determine the component of a.

CE Statics Lecture 6.

The Dot Product (MAT 170) Sections 6.7

10.6 Vectors in Space.

The Scalar or Dot Product Lecture V1.2 Example 4 Moodle.

10.5 The Dot Product. Theorem Properties of Dot Product If u, v, and w are vectors, then Commutative Property Distributive Property.

Phy 212: General Physics II Chapter : Topic Lecture Notes.

Copyright © 2014 John Wiley & Sons, Inc. All rights reserved.

Vectors and Scalars Vector and scalar quantities Adding vectors geometrically Components Unit Vectors Dot Products Cross Products pps by C Gliniewicz.

Chapter 3: VECTORS 3-2 Vectors and Scalars 3-2 Vectors and Scalars

Scalar and Vector Fields

Vectors By Scott Forbes. Vectors  Definition of a Vector Definition of a Vector  Addition Addition  Multiplication Multiplication  Unit Vector Unit.

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.

Chapter 3. Vector 1. Adding Vectors Geometrically

6.4 Vectors and Dot Products

8.6.1 – The Dot Product (Inner Product). So far, we have covered basic operations of vectors – Addition/Subtraction – Multiplication of scalars – Writing.

2009 Physics 2111 Fundamentals of Physics Chapter 3 1 Fundamentals of Physics Chapter 3 Vectors 1.Vectors & Scalars 2.Adding Vectors Geometrically 3.Components.

Chapter 3 : Vectors - Introduction - Addition of Vectors - Subtraction of Vectors - Scalar Multiplication of Vectors - Components of Vectors - Magnitude.

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

Basic Laws Of Math x

Scalars A scalar is any physical quantity that can be completely characterized by its magnitude (by a number value) A scalar is any physical quantity that.

Section 10.2a VECTORS IN THE PLANE. Vectors in the Plane Some quantities only have magnitude, and are called scalars … Examples? Some quantities have.

Vectors. Vectors: magnitude and direction Practice.

Vectors What is Vector?  In elementary mathematics, physics, and engineering, a Euclidean vector is a geometric object that has both a magnitude (or length)

Physical quantities which can completely be specified by a number (magnitude) having an appropriate unit are known as Scalar Quantities. Scalar quantities.

Vectors Vectors are represented by a directed line segment its length representing the magnitude and an arrow indicating the direction A B or u u This.

ch46 Vectors by Chtan FYKulai

Geometric Vectors 8-1. What is a vector? Suppose we are both traveling 65mph on Highway 169 and we pass each other going opposite directions. I’m heading.

2-D motion (no projectiles – yet) Physics Chapter 3 section 1 Pages

Vectors. He takes off from Philadelphia International Airport He flies 20 miles North He then flies 10 miles at a heading 80° East of North Distance =

Assigned work: pg.377 #5,6ef,7ef,8,9,11,12,15,16 Pg. 385#2,3,6cd,8,9-15 So far we have : Multiplied vectors by a scalar Added vectors Today we will: Multiply.

Lecture 2 Vectors.

Vectors A vector quantity has both magnitude (size) and direction A scalar quantity only has size (i.e. temperature, time, energy, etc.) Parts of a vector:

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

Vectors in Two Dimensions. VECTOR REPRESENTATION A vector represents those physical quantities such as velocity that have both a magnitude and a direction.

Vectors Vectors vs. Scalars Vector Addition Vector Components

ME 201 Engineering Mechanics: Statics Chapter 2 – Part E 2.9 Dot Product.

12.3 The Dot Product. The dot product of u and v in the plane is The dot product of u and v in space is Two vectors u and v are orthogonal  if they meet.

A vector v is determined by two points in the plane: an initial point P (also called the “tail” or basepoint) and a terminal point Q (also called the “head”).

Chapter 3 Lecture 5: Vectors HW1 (problems): 1.18, 1.27, 2.11, 2.17, 2.21, 2.35, 2.51, 2.67 Due Thursday, Feb. 11.

Are the quantities that has magnitude only only  Length  Area  Volume  Time  Mass Are quantities that has both magnitude and a direction in space.

SCALARS & VECTORS. Physical Quantities All those quantities which can be measured are called physical quantities. Physical Quantities can be measured.

6.4 Vectors and Dot Products Objectives: Students will find the dot product of two vectors and use properties of the dot product. Students will find angles.

Math /7.5 – Vectors 1. Suppose a car is heading NE (northeast) at 60 mph. We can use a vector to help draw a picture (see right). 2.

Chapter 3 Vectors.

Sample Problem 3.1 e) Although each of the forces in parts b), c), and d) produces the same moment as the 100 lb force, none are of the same magnitude.

Outline Addition and subtraction of vectors Vector decomposition

How do we add and subtract vectors?

Law of sines Law of cosines Page 326, Textbook section 6.1

By: Engr. Hinesh Kumar Lecturer I.B.T, LUMHS, Jamshoro

Copyright © 2014 John Wiley & Sons, Inc. All rights reserved.

Vectors, Linear Combinations and Linear Independence

Chapter 3 Vectors.

8.6 Vectors in Space.

Unit 2: Algebraic Vectors

VECTORS Dr. Shildneck.

VECTORS Dr. Shildneck.

Vectors An Introduction.

6.1 Vectors in the Plane.

Chapter 7 Work and Energy

Chapter 7 Work and Energy

Chapter 3 Vectors Questions 3-1 Vectors and Scalars

Week 2 Vectors in Physics.

Honors Precalculus 4/19/18 IDs on and showing

Scalar and vector quantities

Vectors Tip or head: D Tail: C

Presentation transcript:

The scalar product of two vectors A and B is equal to the magnitude of vector A times the projection of B onto the direction of vector A. Consider two vectors A and B, the angle between them is . Work, Energy and Power Commutative Law for Dot Product

Where B A represents the projection of vector B onto the direction of vector A. Work, Energy and Power Commutative Law for Dot Product

Where A B represents the projection of vector A onto the direction of B vector. Similarly, Work, Energy and Power Commutative Law for Dot Product

This shows that the dot product of two vectors does not change with the change in the order of the vectors to be multiplied. This fact is known as the commutative of dot product. Work, Energy and Power Commutative Law for Dot Product

According to distributive law for dot product: Consider three vectors A, B and C.Geometric interpretation of dot product by drawing projection (Fig). First we obtain the sum of vectors B and C by head to tail rule then we draw projection OC A and OR A from the terminal point of vector (B+C) respectively onto the direction of A.Fig Work, Energy and Power Distributive Law for Dot Product

Work, Energy and Power Distributive Law for Dot Product The dot product A. (B + C) is equal to the projection of vector (B + C) onto the direction of A multiplied by the magnitude of A. i.e.